Communication apparatus and communication method

ABSTRACT

A communication apparatus includes a signal processor that determines a transmission timing and/or a frequency, wherein the transmission timing and/or the frequency for each of a plurality of terminals is located within a frame corresponding to a communicable range. The communication apparatus includes a weighting synthesizer that applies weights to each of a plurality of modulated symbol sequences and transmits the weighted plurality of modulated symbol sequences from an antenna element. The number of modulated symbol sequences that can be simultaneously transmitted in the same period of time and the same frequency band is different depending on communicable ranges in each of the plurality of frames, each of the plurality of frames including subframes. The signal processor allocates, to each of the subframes, one or more modulated symbol sequences, the number of which is equal to or fewer than the number of modulated symbol sequences that can be simultaneously transmitted.

BACKGROUND 1. Technical Field

The present disclosure relates to a communication apparatus and acommunication method.

2. Description of the Related Art

In wireless communication, a massive multiple-input and multiple-output(MIMO) method, which is a transmission method in which a large number ofantennas are used, is being examined in order to increase the capacityof base stations, access points, and the like.

In Japanese Unexamined Patent Application Publication (Translation ofPCT Application) No. 2015-523757 and E. G. Larsson, O. Edfors, F.Tufvesson, and T. L. Marzetta, “Massive MIMO for next generationwireless systems”, IEEE Communication Magazine, vol. 52, no. 2, pp.186-195, February 2014, for example, a method for improving capacity bycausing base stations and access points to generate a plurality of beamsand simultaneously access a plurality of terminals is disclosed.

SUMMARY

Radio waves at frequencies of 5 GHz or higher, or more specificallyradio waves in a 5 GHz band, a 20 GHz band, or a 60 GHz band, forexample, attenuate faster than radio waves in a microwave band, and acommunication distance range becomes narrower. In order to reduce thepower consumption of the entire communication system or to reduce coststaken in the communication system, it is desired to “decrease the numberof base stations and access points while securing communicable areas”.As a method for achieving this, it is desirable to widen communicationdistance ranges of each of the base stations and each of the accesspoints.

In Japanese Unexamined Patent Application Publication (Translation ofPCT Application) No. 2015-523757 and E. G. Larsson, O. Edfors, F.Tufvesson, and T. L. Marzetta, “Massive MIMO for next generationwireless systems”, IEEE Communication Magazine, vol. 52, no. 2, pp.186-195, February 2014, however, an examination for wideningcommunication distance ranges of base stations and access points whenthe massive MIMO method is used has not been carried out.

In one general aspect, the techniques disclosed here feature acommunication apparatus for performing directive transmission using aplurality of antenna elements. The communication apparatus includes asignal processor that determines a transmission timing and/or afrequency for transmitting a modulated symbol sequence for each of aplurality of terminals, wherein the transmission timing and/or thefrequency for each of the plurality of terminals is located within aframe corresponding to a communicable range to the terminal belongs, theframe being one of a plurality of frames defined by time and frequencybands and a weighting synthesizer that applies weights to each of theplurality of modulated symbol sequences and transmitting the weighedplurality of modulated symbol sequences from the plurality of antennaelements. The number of modulated symbol sequences that can besimultaneously transmitted in a same period of time and a same frequencyband is different depending on communicable ranges in each of theplurality of frames, each of the plurality of frames including aplurality of subframes specified by performing time division and/orfrequency division. The signal processor allocates, to each of theplurality of subframes, one or more modulated symbol sequences, thenumber of which is equal to or fewer than the number of modulated symbolsequences that can be simultaneously transmitted.

According to the aspect of the present disclosure, when the massive MIMOmethod is used, the number of base stations and access points can bedecreased while securing communicable areas by widening communicationdistance ranges of base stations and access points.

It should be noted that these general or specific aspects may beimplemented as a system, a method, an integrated circuit (IC), acomputer program, a recording medium, or any selective combinationthereof.

Additional benefits and advantages of the disclosed embodiments willbecome apparent from the specification and drawings. The benefits and/oradvantages may be individually obtained by the various embodiments andfeatures of the specification and drawings, which need not all beprovided in order to obtain one or more of such benefits and/oradvantages.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a diagram illustrating an example of the configuration of abase station according to an embodiment;

FIG. 2 is a diagram illustrating an example of the configuration of anantenna unit;

FIG. 3 is a diagram illustrating the configuration of a base stationdifferent from that illustrated in FIG. 1 according to the embodiment;

FIG. 4 is a diagram illustrating an example of the configuration of aterminal;

FIG. 5 is a diagram illustrating an example of the configuration of anantenna unit;

FIG. 6 is a diagram illustrating the configuration of a terminaldifferent from that illustrated in FIG. 4 according to the embodiment;

FIG. 7 is a diagram illustrating an example of a communication state ata time when a base station is transmitting four transmission beams;

FIG. 8 is a diagram illustrating an example of a state of modulatedsignals transmitted from the base station in the communication state ofthe base station and terminals illustrated in FIG. 7;

FIG. 9 is a diagram illustrating an example of a communication state ata time when the base station is transmitting two transmission beams;

FIG. 10 is a diagram illustrating an example of a state of modulatedsignals transmitted from the base station in the communication state ofthe base station and terminals illustrated in FIG. 9;

FIG. 11 is a diagram illustrating an example of communication performedbetween a base station and each terminal;

FIG. 12 is a diagram illustrating an example of a state of the basestation and the terminals;

FIG. 13 is a diagram illustrating an example of the state of the basestation and the terminals;

FIG. 14 is a diagram illustrating an example of a state of modulatedsignals transmitted from the base station;

FIG. 15 is a diagram illustrating an example of the communication stateof the base station and the terminals according to the presentembodiment;

FIG. 16 is a diagram illustrating “limits of communicable ranges” of abase station;

FIG. 17 is a diagram illustrating a first example of the “frameconfiguration of one or more transmission beams (or modulated signals)”transmitted from a base station;

FIG. 18 is a diagram illustrating a second example of the “frameconfiguration of one or more transmission beams (or modulated signals)”transmitted from the base station;

FIG. 19A is a diagram illustrating an example of transmission beamsincluded in each frame;

FIG. 19B is a diagram illustrating an example of streams included ineach frame;

FIG. 20 is a diagram illustrating a first example of the configurationof subframes of an i-th frame;

FIG. 21 is a diagram illustrating an example of a communication state ofthe base station and terminals according to the present embodiment;

FIG. 22 is a diagram illustrating a second example of the configurationof the subframes included in the i-th frame;

FIG. 23 is a diagram illustrating a third example of the configurationof the subframes included in the i-th frame;

FIG. 24 is a diagram illustrating a fourth example of the configurationof the subframes included in the i-th frame;

FIG. 25 is a diagram illustrating a fifth example of the configurationof the subframes included in the i-th frame;

FIG. 26 is a diagram illustrating an example of the “frame configurationof one or more streams (or modulated signals)” transmitted from a basestation;

FIG. 27 is a diagram illustrating an example of division in a timedirection;

FIG. 28 is a diagram illustrating an example of division in a frequencydirection; and

FIG. 29 is a diagram illustrating an example of the basic configurationof a communication apparatus according to the embodiment.

DETAILED DESCRIPTION

Embodiments of the present disclosure will be described in detailhereinafter with reference to the drawings. The following embodimentsare examples, and the present disclosure is not limited to theseembodiments.

Embodiment

FIG. 1 is a diagram illustrating an example of the configuration of abase station according to the present embodiment. The base stationillustrated in FIG. 1 may be an access point.

There are first to M-th pieces of information 101_1 to 101_M,respectively. That is, there is an m-th piece of information 101_m (m isan integer equal to or larger than 1 but equal to or smaller than M, andM is an integer equal to or larger than 2). Not all of the first to M-thpieces of information, however, need to exist.

If there are a first terminal, a second terminal, . . . , and a U-thterminal (U is an integer equal to or smaller than M) as communicationtargets, an i-th piece of information “does not exist” or “is data to betransmitted to one of the terminals”.

A signal processor 102 receives the first piece of information (101_1),the second piece of information (101_2), . . . , the M-th piece ofinformation (101_M), and a control signal 159. The signal processor 102processes signals on the basis of information such as “informationregarding a method of error correction coding (e.g., a code rate or acode length (block length))”, “information regarding a modulationmethod”, “information regarding precoding”, and a “transmission method(e.g., a multiplexing method)” included in the control signal 159. Thesignal processor 102 then outputs a processed signal 103_1, a processedsignal 103_2, . . . , and a processed signal 103_M. That is, the signalprocessor 102 outputs a processed signal 103_m. Not all of the processedsignals 103_1 to 103_M, however, need to exist.

At this time, the signal processor 102 performs error correction codingon the m-th piece of information (101_m) and then performs mapping usingthe determined modulation method. As a result, a baseband signal isobtained. The signal processor 102 then collects baseband signalscorresponding to the pieces of information and performs precoding.Alternatively, the signal processor 102 may employ, for example,orthogonal frequency-division multiplexing (OFDM).

A radio unit 104_1 receives the processed signal 103_1 and the controlsignal 159, performs processing such as band limitation, frequencyconversion, and amplification on the basis of the control signal 159,and outputs a modulated signal 105_1. The modulated signal 105_1 isoutput from an antenna unit 106_1 as a radio wave.

Similarly, a radio unit 104_2 receives the processed signal 103_2 andthe control signal 159, performs processing such as band limitation,frequency conversion, and amplification on the basis of the controlsignal 159, and outputs a modulated signal 105_2. The modulated signal105_2 is output from an antenna unit 106_2 as a radio wave.

Similarly, a radio unit 104_M receives the processed signal 103_M andthe control signal 159, performs processing such as band limitation,frequency conversion, and amplification on the basis of the controlsignal 159, and outputs a modulated signal 105_M. The modulated signal105_M is output from an antenna unit 106_M as a radio wave.

If there is no processed signal, the radio units need not perform theabove processing.

Radio units 153 receive signals 152 received by reception antennas 151,perform processing such as frequency conversion, and output basebandsignals 154. The received signals 152 include one or a plurality ofreceived signals, the reception antennas 151 include one or a pluralityof antennas, the radio units 153 include one or a plurality of radiounits, and the baseband signals 154 include one or a plurality ofbaseband signals.

A signal processor 155 receives the baseband signals 154 and performsdemodulation and error correction decoding. The signal processor 155also performs processing such as time synchronization, frequencysynchronization, and channel estimation. At this time, because thesignal processor 155 receives and processes modulated signalstransmitted from one or more terminals, the signal processor 155 obtainscontrol information transmitted from the terminals as well as datatransmitted from the terminals. The signal processor 155, therefore,outputs data 156 corresponding to the one or more terminals and controlinformation 157 corresponding to the one or more terminals. The data 156includes one or plurality of pieces of data, and the control information157 includes one or plurality of pieces of control information.

A setting unit 158 receives the control information 157, determines a“method of error correction coding (e.g., a code rate or a code length(block length))”, a “modulation method”, a “precoding method”, a“transmission method”, “settings of antennas”, and the like on the basisof the control information 157, and outputs a control signal 159including the determined information.

The antennas 106_1, 106_2, . . . , and 106_M receive the control signal159. The configuration of the antennas 106_1, 106_2, . . . , and 106_Mwill be described with reference to FIG. 2 while taking an antenna unit106_m as an example.

FIG. 2 is a diagram illustrating an example of the configuration of theantenna unit 106_m. The antenna unit 106_m is assumed to include aplurality of antennas as illustrated in FIG. 2. Although FIG. 2illustrates four antennas, the number of antennas is not limited tofour. It is sufficient that each of the antenna units 106_1, 106_2, . .. , and 106_M includes a plurality of antennas. In addition, the numberof antennas included in each of the antenna units 106_1, 106_2, . . . ,and 106_M need not be the same.

A distributor 202 receives a transmission signal 201 (corresponds to amodulated signal 105_m illustrated in FIG. 1), distributes thetransmission signal 201, and outputs signals 203_1, 203_2, 203_3, and203_4.

A multiplication unit 204_1 receives the signal 203_1 and a controlsignal 200 (corresponds to the control signal 159 illustrated in FIG.1), multiplies the signal 203_1 by a coefficient W1 on the basis ofinformation regarding a multiplication coefficient included in thecontrol signal 200, and outputs a resultant signal 205_1. Thecoefficient W1 is defined by a complex number. W1, therefore, can be areal number. If the signal 203_1 is denoted by v1(t), the resultantsignal 205_1 can be represented as W1×v1(t) (t denotes time). Theresultant signal 205_1 is then output from an antenna 206_1 as a radiowave.

Similarly, a multiplication unit 204_2 receives the signal 203_2 and thecontrol signal 200, multiplies the signal 203_2 by a coefficient W2 onthe basis of the information regarding the multiplication coefficientincluded in the control signal 200, and outputs a resultant signal205_2. The coefficient W2 is defined by a complex number. W2, therefore,can be a real number. If the signal 203_2 is denoted by v2(t), theresultant signal 205_2 can be represented as W2×v2(t). The resultantsignal 205_2 is then output from an antenna 206_2 as a radio wave.

Similarly, a multiplication unit 204_3 receives the signal 203_3 and thecontrol signal 200, multiplies the signal 203_3 by a coefficient W3 onthe basis of the information regarding the multiplication coefficientincluded in the control signal 200, and outputs a resultant signal205_3. The coefficient W3 is defined by a complex number. W3, therefore,can be a real number. If the signal 203_3 is denoted by v3(t), theresultant signal 205_3 can be represented as W3×v3(t). The resultantsignal 205_3 is then output from an antenna 206_3 as a radio wave.

Similarly, a multiplication unit 204_4 receives the signal 203_4 and thecontrol signal 200, multiplies the signal 203_4 by a coefficient W4 onthe basis of the information regarding the multiplication coefficientincluded in the control signal 200, and outputs a resultant signal205_4. The coefficient W4 is defined by a complex number. W4, therefore,can be a real number. If the signal 203_4 is denoted by v4(t), theresultant signal 205_4 can be represented as W4×v4(t). The resultantsignal 205_4 is then output from an antenna 206_4 as a radio wave.

An absolute value of W1, an absolute value of W2, an absolute value ofW3, and an absolute value of W4 may be the same.

The radio waves output from the antennas 206_1 to 206_4 are certaintransmission beams.

In the configuration of the base station illustrated in FIGS. 1 and 2, asetting unit 158 determines the configuration of a frame, which will bedescribed later. Information regarding the determined frameconfiguration is included in the control signal 159 to be output. Thesignal processor 102 assigns the processed signals to a frame on thebasis of the information regarding the frame configuration included inthe control signal 159. The radio units 104_1 to 104_M and the antennaunits 106_1 to 106_M perform the processing on the basis of theinformation regarding the frame configuration included in the controlsignal 159 and a process for transmitting the signals in accordance withthe frame configuration.

In the present embodiment, the configuration of a base station may bedifferent from that described with reference to FIGS. 1 and 2.

FIG. 3 is a diagram illustrating the configuration of a base stationdifferent from that illustrated in FIG. 1 according to the presentembodiment. In FIG. 3, the same components as those illustrated in FIG.1 are given the same reference numerals, and description thereof isomitted.

A weighting synthesizer 301 receives the modulated signal 105_1, themodulated signal 105_2, . . . , the modulated signal 105_M, and thecontrol signal 159. The weighting synthesizer 301 then performsweighting synthesis on the modulated signal 105_1, the modulated signal105_2, . . . , and the modulated signal 105_M on the basis ofinformation regarding the weighting synthesis included in the controlsignal 159 and outputs resultant signals 302_1, 302_2, . . . , and 302_K(K is an integer equal to or larger than 1). The resultant signal 302_1is output from an antenna 303_1 as a radio wave. Similarly, theresultant signal 302_2 is output from an antenna 303_2 as a radio wave.Similarly, the resultant signal 302_K is output from an antenna 303_K asa radio wave.

If the modulated signal 105_m is denoted by x_(m)(t), a resultant signal302_k (k is an integer equal to or larger than 1 but equal to or smallerthan K) is denoted by y_(k)(t), and a weighting coefficient is denotedby A_(km), y_(k)(t) is represented by the following expression (1) (tdenotes time).

$\begin{matrix}\begin{matrix}{{y_{k}(t)} = {{A_{k\; 1} \times {x_{1}(t)}} + {A_{k\; 2} \times {x_{2}(t)}} + \ldots + {A_{k\; M} \times {x_{M}(t)}}}} \\{= {\sum\limits_{m = 1}^{M}\; {A_{k\; M} \times {x_{M}(t)}}}}\end{matrix} & (1)\end{matrix}$

In expression (1), A_(km) is a value that can be defined by a complexnumber. A_(km), therefore, can be a real number.

Next, the configuration a terminal according to the present embodimentwill be described.

FIG. 4 is a diagram illustrating an example of the configuration of aterminal. Antenna units 401_1, 401_2, . . . , and 401_N receive acontrol signal 410 (N is an integer equal to or larger than 1).

A radio unit 403_1 receives a received signal 402_1 received by theantenna unit 401_1, performs processing such as frequency conversion onthe received signal 402_1 on the basis of the control signal 410, andoutputs a baseband signal 404_1.

Similarly, a radio unit 403_2 receives a received signal 402_2 receivedby the antenna unit 401_2, performs processing such as frequencyconversion on the received signal 402_2 on the basis of the controlsignal 410, and outputs a baseband signal 404_2.

Similarly, a radio unit 403_N receives a received signal 402_N receivedby the antenna unit 401_N, performs processing such as frequencyconversion on the received signal 402_N on the basis of the controlsignal 410, and outputs a baseband signal 404_N.

Not all the radio units 403_1, 403_2, . . . , and 403_N, however, needto operate. Not all the baseband signals 404_1, 404_2, . . . , and404_N, therefore, might not exist.

A signal processor 405 receives the baseband signals 404_1, 404_2, . . ., and 404_N and the control signal 410, performs processing such asdemodulation and error correction decoding on the basis of the controlsignal 410, and outputs data 406, transmission control information 407,and control information 408. The signal processor 405 also performsprocessing such as time synchronization, frequency synchronization, andchannel estimation.

A setting unit 409 receives the control information 408, makes settingsrelating to a reception method, and outputs the control signal 410.

A signal processor 452 receives information 451 and the transmissioncontrol information 407, performs processing such as error correctioncoding and mapping based on a determined modulation method, and outputsbaseband signals 453.

Radio units 454 receive the baseband signals 453, perform processingsuch as band limitation, frequency conversion, and amplification, andoutputs transmission signals 455. The transmission signals 455 areoutput from transmission antennas 456 as radio waves. The radio units454 include one or a plurality of radio units, the baseband signals 453include one or a plurality of baseband signals, the transmission signals455 include one or a plurality of transmission signals, and thetransmission antennas 456 include one or a plurality of antennas.

Next, the configuration of the antennas 401_1, 401_2, . . . , and 401_Nwill be described with reference to FIG. 2 while taking an antenna unit401_n (n is an integer equal to or larger than 1 but equal to or smallerthan N) as an example.

FIG. 5 is a diagram illustrating an example of the configuration of theantenna unit 401_n. As illustrated in FIG. 5, the antenna unit 401_n isassumed to include a plurality of antennas. Although FIG. 5 illustratesfour antennas, the number of antennas is not limited to four. It issufficient that each of the antenna units 401_1, 401_2, . . . , and401_N includes a plurality of antennas. In addition, the number ofantennas included in each of the antenna units 401_1, 401_2, . . . , and401_N need not be the same.

A multiplication unit 503_1 receives a received signal 502_1 received byan antenna 501_1 and a control signal 500 (corresponds to the controlsignal 410 illustrated in FIG. 4), multiplies the received signal 502_1by a coefficient D1 on the basis of information regarding amultiplication coefficient included in the control signal 500, andoutputs a resultant signal 504_1. The coefficient D1 is defined by acomplex number. D1, therefore, can be a real number. If the receivedsignal 502_1 is denoted by e1(t), the resultant signal 504_1 can berepresented as D1×e1(t) (t denotes time).

Similarly, a multiplication unit 503_2 receives a received signal 502_2received by an antenna 501_2 and the control signal 500, multiplies thereceived signal 502_2 by a coefficient D2 on the basis of theinformation regarding the multiplication coefficient included in thecontrol signal 500, and outputs a resultant signal 504_2. Thecoefficient D2 can be defined by a complex number. D2, therefore, can bea real number. If the received signal 502_2 is denoted by e2(t), theresultant signal 504_2 can be represented as D2×e2(t).

Similarly, a multiplication unit 503_3 receives a received signal 502_3received by an antenna 501_3 and the control signal 500, multiplies thereceived signal 502_3 by a coefficient D3 on the basis of theinformation regarding the multiplication coefficient included in thecontrol signal 500, and outputs a resultant signal 504_3. Thecoefficient D3 can be defined by a complex number. D3, therefore, can bea real number. If the received signal 502_3 is denoted by e3(t), theresultant signal 504_3 can be represented as D3×e3(t).

Similarly, a multiplication unit 503_4 receives a received signal 502_4received by an antenna 501_4 and the control signal 500, multiplies thereceived signal 502_4 by a coefficient D4 on the basis of theinformation regarding the multiplication coefficient included in thecontrol signal 500, and outputs a resultant signal 504_4. Thecoefficient D4 can be defined by a complex number. D4, therefore, can bea real number. If the received signal 502_4 is denoted by e4(t), theresultant signal 504_4 can be represented as D4×e4(t).

A synthesizer 505 receives the resultant signals 504_1, 504_2, 504_3,and 504_4, adds the resultant signals 504_1, 504_2, 504_3, and 504_4together, and outputs a resultant signal 506 (corresponds to a receivedsignal 402_i illustrated in FIG. 4). The resultant signal 506 isrepresented as D1×e1(t), +D2×e2(t)+D3×e3(t)+D4×e4(t).

In the present embodiment, the configuration of a terminal may bedifferent from that described with reference to FIGS. 4 and 5.

FIG. 6 is a diagram illustrating the configuration of a terminaldifferent from that illustrated in FIG. 4 according to the presentembodiment. In FIG. 6, the same components as those illustrated in FIG.4 are given the same reference numerals, and description thereof isomitted.

A multiplication unit 603_1 receives a received signal 602_1 received byan antenna 601_1 and the control signal 410, multiplies the receivedsignal 602_1 by a coefficient G1 on the basis of information regarding amultiplication coefficient included in the control signal 410, andoutputs a resultant signal 604_1. The coefficient G1 can be defined by acomplex number. G1, therefore, can be a real number. If the receivedsignal 602_1 is denoted by c1(t), the resultant signal 604_1 can berepresented as G1×c1(t) (t denotes time).

Similarly, a multiplication unit 603_2 receives a received signal 602_2received by an antenna 601_2 and the control signal 410, multiplies thereceived signal 602_2 by a coefficient G2 on the basis of theinformation regarding the multiplication coefficient included in thecontrol signal 410, and outputs a resultant signal 604_2. Thecoefficient G2 can be defined by a complex number. G2, therefore, can bea real number. If the received signal 602_2 is denoted by c2(t), theresultant signal 604_2 can be represented as G2×c2(t).

Similarly, a multiplication unit 603_L receives a received signal 602_Lreceived by an antenna 601_L and the control signal 410, multiplies thereceived signal 602_L by a coefficient GL on the basis of theinformation regarding the multiplication coefficient included in thecontrol signal 410, and outputs a resultant signal 604_L. Thecoefficient GL can be defined by a complex number. GL, therefore, can bea real number. If the received signal 602_L is denoted by cL(t), theresultant signal 604_L can be represented as GL×cL(t).

Similarly, a multiplication unit 603_1 (1 is an integer equal to orlarger than 1 but equal to or smaller than L, and L is an integer equalto or larger than 2) receives a received signal 602_I received by anantenna 601_I and the control signal 410, multiplies the received signal602_I by a coefficient GI on the basis of the information regarding themultiplication coefficient included in the control signal 410, andoutputs a resultant signal 604_1. The coefficient GI can be defined by acomplex number. GI, therefore, can be a real number. If the receivedsignal 602_1 is denoted by c1(t), the resultant signal 604_I can berepresented as GI×cl(t).

A processor 605 receives the resultant signal 604_1, the resultantsignal 604_2, . . . , the resultant signal 604_L, and the control signal410, processes signals on the basis of the control signal 410, andoutputs processed signals 606_1, 606_2, . . . , and 606_N (N is aninteger equal to or larger than 2).

At this time, if a resultant signal 604_1 is denoted by p_(l)(t) and aprocessed signal 606_n is denoted by r_(n)(t), r_(n)(t) is representedby the following expression (2) (n is an integer equal to or larger than1 but equal to or smaller than N).

$\begin{matrix}\begin{matrix}{{r_{n}(t)} = {{B_{n\; 1} \times {p_{1}(t)}} + {B_{n\; 2} \times {p_{2}(t)}} + \ldots + {B_{nL} \times {p_{L}(t)}}}} \\{= {\sum\limits_{l = 1}^{L}\; {B_{nl} \times {p_{l}(t)}}}}\end{matrix} & (2)\end{matrix}$

In expression (2), B_(nl) is a value that can be defined by a complexnumber. B_(nl), therefore, can be a real number.

As described above, the base station and the terminals according to thepresent embodiment each include a plurality of antennas or an antennaunit including a plurality of antennas and can control directivity. Areception device of the terminal “need not control directivity”. In thiscase, the terminal need not include a plurality of antennas. That is,the terminal includes one antenna. When the terminal includes oneantenna, the base station controls directivity.

Next, a communication state when a base station and terminals arecontrolling the antenna directivity thereof in the present embodimentwill be described.

FIG. 7 is a diagram illustrating an example of a communication state ata time when a base station 700 is transmitting four transmission beams.In FIG. 7, there are the base station 700 and first to fourth terminals701 to 704, respectively. The base station 700 transmits a modulatedsignal for the first terminal (701), a modulated signal for the secondterminal (702), a modulated signal for the third terminal (703), and amodulated signal for the fourth signal (704) using the same period oftime and the same frequency (band). FIG. 7 illustrates a situation atthis time.

The base station 700 directs an antenna to the first terminal (701) asindicated by a transmission beam 711, an antenna to the second terminal(702) as indicated by a transmission beam 712, an antenna to the thirdterminal (703) as indicated by a transmission beam 713, and an antennato the fourth terminal (704) as indicated by a transmission beam 714.That is, the base station 700 directs the four transmission beams to thefour terminals, respectively. In doing so, interference between themodulated signal for the first terminal (701), the modulated signal forthe second terminal (702), the modulated signal for the third terminal(703), and the modulated signal for the fourth terminal (704) isreduced, and the first to fourth terminals can secure high datareception quality. In order to achieve this, the base station 700 hasthe configuration illustrated in FIG. 1 or 3.

Although the first terminal (701) directs an antenna to the base station700 as indicated by a beam 721, the second terminal (702) directs anantenna to the base station 700 as indicated by a beam 722, the thirdterminal (703) directs an antenna to the base station 700 as indicatedby a beam 723, and the fourth terminal (704) directs an antenna to thebase station 700 as indicated by a beam 724 in FIG. 7, the directivityof the antennas is not limited to this.

An ellipse 799 illustrated in FIG. 7 indicates a limit of a communicablerange of the terminals at a time when the base station 700 transmitsfour transmission beams (or modulated signals). When a terminal islocated within the ellipse 799, the terminal can communicate with thebase station 700.

Although the base station 700 transmits four transmission beams (ormodulated signals) in FIG. 7, the transmission beams (or modulatedsignals) may be modulated symbol sequences, instead. In this case, inFIG. 7, the base station 700 transmits four modulated symbol sequences.The ellipse 799 indicates a limit of a communicable range at a time whenthe number of modulated symbol sequences that can be simultaneouslytransmitted in the same period of time and the same frequency band isfour.

Although the limit of the communicable range has an elliptical shape inthe present embodiment, a shape of the limit of the communicable rangeis not limited to an ellipse.

FIG. 8 is a diagram illustrating an example of a state of the modulatedsignals transmitted from the base station 700 with the base station 700and the terminals in the communication state illustrated in FIG. 7. InFIG. 8, a horizontal axis represents time. FIG. 8(a) illustrates anexample of a frame of a modulated signal for the first terminal. FIG.8(b) illustrates an example of a frame of a modulated signal for thesecond terminal. FIG. 8(c) illustrates an example of a frame of amodulated signal for the third terminal. FIG. 8(d) illustrates anexample of a frame of a modulated signal for the fourth terminal.

As illustrated in FIG. 8, symbols 801 for the first terminal, symbols802 for the second terminal, symbols 803 for the third terminal, andsymbols 804 for the fourth terminal exist at least in a section T1 alongthe time axis. As described above, the base station 700 transmits thesymbols 801 for the first terminal, the symbols 802 for the secondterminal, the symbols 803 for the third terminal, and the symbols 804for the fourth terminal using the same frequency (band). Such atransmission method is called multiuser MIMO (MU-MIMO).

As described above, the ellipse 799 illustrated in FIG. 7 indicates thelimit of the communicable range at a time when the base station 700transmits four transmission beams (or modulated signals). When thenumber of transmission beams (or modulated signals) transmitted from thebase station 700 is different, the limit of the communicable range isdifferent. This is because, as described later, there is a restrictionon the average transmission power of a base station. Next, a limit of acommunicable range when the base station 700 transmits two transmissionbeams (or modulated signals) will be described.

FIG. 9 is a diagram illustrating an example of a communication state ata time when the base station 700 is transmitting two transmission beams.In FIG. 9, the base station 700 transmits a modulated signal for aneleventh terminal (901) and a modulated signal for a twelfth terminal(902) using the same period of time and the same frequency (band). FIG.9 illustrates a situation at this time.

The base station 700 directs an antenna to the eleventh terminal (901)as indicated by a transmission beam 911 and an antenna to the twelfthterminal (902) as indicated by a transmission beam 912. In doing so,interference between the modulated signal for the eleventh terminal(901) and the modulated signal for the twelfth terminal (902) isreduced, and the eleventh and twelfth terminals can secure high datareception quality. In order to achieve this, for example, the basestation 700 has the configuration illustrated in FIG. 1 or 3.

Although the eleventh terminal (901) directs an antenna to the basestation 700 as indicated by a beam 921 and the twelfth terminal (902)directs an antenna to the base station 700 as indicated by a beam 922 inFIG. 9, the directivity of the antennas is not limited to this.

An ellipse 999 illustrated in FIG. 9 indicates a limit of a communicablerange of the terminals at a time when the base station 700 transmits twotransmission beams (or modulated signals). When a terminal is locatedwithin the ellipse 999, the terminal can communicate with the basestation 700. For comparison, FIG. 9 also illustrates the “ellipse 799indicating the limit of the communicable range of the terminals when thebase station transmits four transmission beams (or modulated signals)”illustrated in FIG. 7.

An upper limit of the sum of average transmission power is determined tobe a certain value regardless of the number of transmission beams (orthe number of modulated signals to be transmitted). As the number oftransmission beams to be transmitted from the base station increases,therefore, the limit of the communicable range of the terminals becomescloser to the base station. As a result, as illustrated in FIG. 9, theellipse 799 indicating the “limit of the communicable range of theterminals when the base station transmits four transmission beams (ormodulated signals)” is closer to the base station 700 than the ellipse999 indicating the “limit of the communicable range of the terminalswhen the base station transmits two transmission beams (or modulatedsignals)” is.

FIG. 10 is a diagram illustrating an example of a state of the modulatedsignals transmitted from the base station 700 illustrated in FIG. 9 withthe base station and the terminals in the communication stateillustrated in FIG. 9. FIG. 10(a) illustrates an example of a frame ofthe modulated signal for the eleventh terminal over horizontal axistime. FIG. 10(b) illustrates an example of a frame of the modulatedsignal for the twelfth terminal over the horizontal axis time.

As illustrated in FIG. 10, symbols 1001 for the eleventh terminal andsymbols 1002 for the twelfth terminal exist at least in a section T2along the time axis. As described above, the base station transmits thesymbols 1001 for the eleventh terminal and the symbols 1002 for thetwelfth terminal using the same frequency (band).

FIG. 11 is a diagram illustrating an example of communication between abase station and each terminal. FIG. 11(a) illustrates an example oftransmission symbols transmitted from the base station over horizontalaxis time. FIG. 11(b) illustrates an example of transmission symbolstransmitted from the terminal over the horizontal axis time.

First, as illustrated in FIG. 11, the base station transmits, forexample, base station control information symbols 1101. The symbolsinclude, for example, PSK (Phase Shift Keying) symbols whose mapping isknown to the terminal.

The terminal receives the base station control information symbols 1101transmitted from the base station and performs estimation of atransmission environment (estimation of a channel state). The terminalthen transmits terminal control information symbols 1151 includinginformation regarding the channel state (e.g., channel state information(CSI)). The terminal may also transmit terminal data symbols 1152.

The base station receives the terminal control information symbols 1151and the terminal data symbols 1152 transmitted from the terminal. Thebase station then obtains the information regarding the channel stateincluded in the terminal control information symbols 1151 and amultiplication coefficient (e.g., one of the multiplication coefficientsused by the multiplication units 204_1 to 204_4 illustrated in FIG. 2 orthe coefficient for the weighting synthesis used by the weightingsynthesizer 301 illustrated in FIG. 3) for generating transmissionsignals to be transmitted to the terminal. The base station transmitsbase station control information symbols 1102 and base station datasymbols 1103. At this time, the base station generates a transmissionbeam using the obtained multiplication coefficient.

The base station generates transmission beams for a plurality ofterminals by communicating the symbols illustrated in FIG. 11 with theplurality of terminal. As a result, the base station transmits thetransmission beams illustrated in FIG. 7 or 9.

In the following description, too, a base station communicates with aterminal as illustrated in FIG. 11 when the base station transmits atransmission beam to the terminal. FIG. 11, however, illustrates just anexample, and a method for sharing a transmission environment state of amodulated signal transmitted from a base station to a terminal is notlimited to that illustrated in FIG. 11.

FIG. 12 is a diagram illustrating an example of a state of the basestation and the terminals. The same components as those illustrated inFIG. 7 or 9 are given the same reference numerals. As described withreference to FIG. 7, it is assumed that the base station 700 istransmitting the modulated signal for the first terminal (701), themodulated signal for the second terminal (702), the modulated signal forthe third terminal (703), and the modulated signal for the fourthterminal (704) using the same period of time and the same frequency(band). The base station 700, therefore, directs the antenna to thefirst terminal (701) as indicated by the transmission beam 711, theantenna to the second terminal (702) as indicated by the transmissionbeam 712, the antenna to the third terminal (703) as indicated by thetransmission beam 713, and the antenna to the fourth terminal (704) asindicated by the transmission beam 714. That is, the base station 700directs the four transmission beams to the four terminals, respectively.In this case, since the four terminals are located within the ellipse799, which indicates the “limit of the communicable range of theterminals when the base station transmits four transmission beams (ormodulated signals)”, the base station 700 can communicate with the firstterminal (701), the second terminal (702), the third terminal (703), andthe fourth terminal (704).

Since the eleventh terminal (901) and the twelfth terminal (902) arelocated outside the ellipse 799, which indicates the “limit of thecommunicable range of the terminals when the base station transmits fourtransmission beams (or modulated signals)”, it is assumed that the basestation 700 is not communicating with the eleventh terminal (901) andthe twelfth terminal (902).

FIG. 13 is a diagram illustrating an example of the state of the basestation and the terminals. The same components as those illustrated inFIG. 7 or 9 are given the same reference numerals. As described withreference to FIG. 7, it is assumed that the base station 700 istransmitting the modulated signal for the first terminal (701), themodulated signal for the second terminal (702), the modulated signal forthe third terminal (703), and the modulated signal for the fourthterminal (704) using the same period of time and the same frequency(band). The base station 700, therefore, directs the antenna to thefirst terminal (701) as indicated by the transmission beam 711, theantenna to the second terminal (702) as indicated by the transmissionbeam 712, the antenna to the third terminal (703) as indicated by thetransmission beam 713, and the antenna to the fourth terminal (704) asindicated by the transmission beam 714. That is, the base station 700directs the four transmission beams to the four terminals, respectively.In this case, it is assumed that the base station 700 is communicatingwith the first terminal (701), the second terminal (702), the thirdterminal (703), and the fourth terminal (704). Since the four terminalsare located within the ellipse 799, which indicates the “limit of thecommunicable range of the terminals when the base station transmits fourtransmission beams (or modulated signals)”, the base station 700 cancommunicate with the first terminal (701), the second terminal (702),the third terminal (703), and the fourth terminal (704).

It is then assumed that, in this state, the base station 700 transmitsthe modulated signal for the first terminal (701), the modulated signalfor the second terminal (702), the modulated signal for the thirdterminal (703), the modulated signal for the fourth terminal (704), themodulated signal for the eleventh terminal (901), and the modulatedsignal for the twelfth terminal (902) using the same period of time andthe same frequency (band).

FIG. 14 is a diagram illustrating an example of a state of the modulatesignals transmitted from the base station 700. FIG. 14(a) illustrates anexample of the frame configuration of the modulated signal for the firstterminal over horizontal axis time. FIG. 14(b) illustrates an example ofthe frame configuration of the modulated signal for the second terminalover the horizontal axis time. FIG. 14(c) illustrates an example of theframe configuration of the modulated signal for the third terminal overthe horizontal axis time. FIG. 14(d) illustrates an example of the frameconfiguration of the modulated signal for the fourth terminal over thehorizontal axis time. FIG. 14(e) illustrates an example of the frameconfiguration of the modulated signal for the eleventh terminal over thehorizontal axis time. FIG. 14(f) illustrates an example of the frameconfiguration of the modulated signal for the twelfth terminal over thehorizontal axis time.

It is assumed in FIG. 14 that symbols 1401 for the first terminal,symbols 1402 for the second terminal, symbols 1403 for the thirdterminal, symbols 1404 for the fourth terminal, symbols 1405 for theeleventh terminal, and symbols 1406 for the twelfth terminal exist atleast in a section T3. It is then assumed that the base stationtransmits the symbols 1401 for the first terminal, the symbols 1402 forthe second terminal, the symbols 1403 for the third terminal, thesymbols 1404 for the fourth terminal, the symbols 1405 for the eleventhterminal, and the symbols 1406 for the twelfth terminal using the samefrequency (band).

When the base station 700 transmits the modulated signals illustrated inFIG. 14, the base station 700 transmits six transmission beams in FIG.13. As described above, the ellipse 799 illustrated in FIG. 13 indicatesthe “limit of the communicable range of the terminals when the basestation transmits four transmission beams (or modulated signals)”. Thelimit of the communicable range of the terminals when the base station700 transmits the modulated signals illustrated in FIG. 14, that is, thebase station 700 transmits six transmission beams, is closer to the basestation 700 than the ellipse 799 is. There can be a terminal, therefore,for which it is difficult to communicate with the base station 700,depending on positions of the first terminal (701), the second terminal(702), the third terminal (703), the fourth terminal (704), the eleventhterminal (901), and the twelfth terminal (902).

When the state illustrated in FIG. 12 is assumed, for example, it isdifficult for a terminal whose distance from the base station 700 islarger than that of the ellipse 799, which indicates the “limit of thecommunicable range of the terminals when the base station transmits fourtransmission beams (or modulated signals)” from the base station 700 tocommunicate with the base station 700 in the communication modeillustrated in FIG. 7.

It is desired, therefore, to employ a transmission method for the basestation that achieves more flexible communication than in thecommunication mode illustrated in FIG. 7 and expand a communicabledistance range.

In addition, for example, the state illustrated in FIG. 13, that is, astate in which there are more terminals than transmission beams withinthe “limit of the communicable range of the terminals when the basestation transmits a certain number of transmission beams (or modulatedsignals)” is assumed. If the base station is configured to transmitmodulate signals to all the terminals using the same period of time andthe same frequency in this state, a case might occur in which it isdifficult for the base station to transmit the modulated signals to allthe terminals using the same period of time and the same frequency band,since there is the upper limit of average transmission power that can betransmitted from the base station.

A transmission method effective to this problem will be describedhereinafter.

FIG. 15 is a diagram illustrating an example of the communication stateof the base station and the terminals according to the presentembodiment. In FIG. 15, the same components as those illustrated in FIG.7 or 9 are given the same reference numerals, and description thereof isomitted.

The base station 700 transmits the transmission beam 711 for the firstterminal (701), the transmission beam 712 for the second terminal (702),the transmission beam 713 for the third terminal (703), and thetransmission beam 714 for the fourth terminal (704) using the sameperiod of time (referred to as a period tt1) and the same frequency(band). At this time, the terminals may perform directivity control insuch a way as to direct their respective beams (beams 721 to 724) to thebase station 700. The base station 700 also transmits a transmissionbeam 1511 for the eleventh terminal (901) and a transmission beam 1512for the twelfth terminal (902) using the same period of time (referredto as a period tt2) and the same frequency (band). At this time, theeleventh terminal (901) and the twelfth terminal (902) may performdirectivity control in such a way as to direct their respective beams1521 and 1522 to the base station 700. It is assumed that the period tt1and the period tt2 are different from each other.

A method different from above will be described.

The base station 700 transmits the transmission beam 711 for the firstterminal (701), the transmission beam 712 for the second terminal (702),the transmission beam 713 for the third terminal (703), and thetransmission beam 714 for the fourth terminal (704) using the sameperiod of time and the same frequency (band) (frequency (band) ff1). Atthis time, the terminals may perform directivity control in such a wayas to direct their respective beams (beams 721 to 724) to the basestation 700. The base station 700 also transmits the transmission beam1511 for the eleventh terminal (901) and the transmission beam 1512 forthe twelfth terminal (902) using the same period of time and the samefrequency (band) (frequency (band) ff2). At this time, the eleventhterminal (901) and the twelfth terminal (902) may perform directivitycontrol in such a way as to direct their respective beams 1521 and 1522to the base station 700. It is assumed that the frequency (band) ff1 andthe frequency (band) ff2 are different from each other.

The base station 700 thus, when transmitting four transmission beams,transmits the transmission beam for the first terminal (701), thetransmission beam for the second terminal (702), the transmission beamfor the third terminal (703), and the transmission beam for the fourthterminal (704). In this case, since the first terminal (701), the secondterminal (702), the third terminal (703), and the fourth terminal (704)are located within the ellipse 799 indicating the “limit of thecommunicable range of the terminals when the base station transmits fourtransmission beams (or modulated signals)”, the base station 700 cancommunicate with the first terminal (701), the second terminal (702),the third terminal (703), and the fourth terminal (704). In addition,the base station 700 transmits, when transmitting two transmissionbeams, transmits the transmission beam for the eleventh terminal (901)and the transmission beam for the twelfth terminal (902). Since theeleventh terminal (901) and the twelfth terminal (902) are locatedwithin the ellipse 999 indicating the “limit of the communicable rangeof the terminals when the base station transmits two transmission beams(or modulated signals)”, the base station 700 can communicate with theeleventh terminal (901) and the twelfth terminal (902).

Another example of FIG. 15 will be described.

FIG. 16 is a diagram illustrating “limits of communicable ranges” of abase station 1600. FIG. 16 illustrates ellipses indicating the “limitsof the plurality of communicable ranges” around the base station 1600.

An ellipse 1651 indicates a “limit of a communicable range of terminalswhen the base station transmits sixteen transmission beams (or modulatedsignals)”. Communication can be performed within the ellipse 1651insofar as conditions are satisfied.

An ellipse 1652 indicates a “limit of a communicable range of terminalswhen the base station transmits eight transmission beams (or modulatedsignals)”. Communication can be performed within the ellipse 1652insofar as conditions are satisfied.

An ellipse 1653 indicates a “limit of a communicable range of terminalswhen the base station transmits four transmission beams (or modulatedsignals)”. Communication can be performed within the ellipse 1653insofar as conditions are satisfied.

An ellipse 1654 indicates a “limit of a communicable range of terminalswhen the base station transmits two transmission beams (or modulatedsignals)”. Communication can be performed within the ellipse 1654insofar as conditions are satisfied.

An ellipse 1655 indicates a “limit of a communicable range of a terminalwhen the base station transmits one transmission beam (or modulatedsignal)”. Communication can be performed within the ellipse 1655 insofaras conditions are satisfied.

FIG. 17 is a diagram illustrating a first example of the “frameconfiguration of one or more transmission beams (or modulated signals)”transmitted from a base station. The example illustrated in FIG. 17 isan example at a time when the limits of the five communicable rangesillustrated in FIG. 16 have been set.

In FIG. 17, a horizontal axis represents time. There are first to fifthframes 1701_1 to 1701_5, respectively. It is assumed that the firstframe (1701_1), the second frame (1701_2), the third frame (1701_3), thefourth frame (1701_4), and the fifth frame (1701_5) have been subjectedto time-division multiplexing (TDM).

At this time, the first frame (1701_1) is a “frame used by the basestation to transmit up to 16 transmission beams (or modulated signals)”.This frame is used to achieve a communicable area corresponding to anarea within the ellipse 1651 illustrated in FIG. 16.

The second frame (1701_2) is a “frame used by the base station totransmit up to eight transmission beams (or modulated signals)”. Thisframe is used to achieve a communicable area corresponding to an areainside the ellipse 1652 illustrated in FIG. 16.

The second frame (1701_3) is a “frame used by the base station totransmit up to four transmission beams (or modulated signals)”. Thisframe is used to achieve a communicable area corresponding to an areainside the ellipse 1653 illustrated in FIG. 16.

The fourth frame (1701_4) is a “frame used by the base station totransmit up to two transmission beams (or modulated signals)”. Thisframe is used to achieve a communicable area corresponding to an areainside the ellipse 1654 illustrated in FIG. 16.

The second frame (1701_5) is a “frame used by the base station totransmit one transmission beam (or modulated signal)”. This frame isused to achieve a communicable area corresponding to an area inside theellipse 1655 illustrated in FIG. 16.

The first frame (1701_1) exists in a time section t1, the second frame(1701_2) exists in a time section t2, the third frame (1701_3) exists ina time section t3, the fourth frame (1701_4) exists in a time sectiont4, and the fifth frame (1701_5) exists in a time section t5.

At this time, the time section t1, the time section t2, the time sectiont3, the time section t4, and the time section t5 may be fixed timesections, or may be set as necessary. For example, the time sections maybe set in accordance with the number of terminals that the base stationcommunicates with, positions of the terminals, or the like.

In FIG. 17, the first frame (1701_1), the second frame (1701_2), thethird frame (1701_3), the fourth frame (1701_4), and the fifth frame(1701_5) are continuously arranged. Order in which the first frame(1701_1), the second frame (1701_2), the third frame (1701_3), thefourth frame (1701_4), and the fifth frame (1701_5) are transmitted isnot limited to that illustrated in FIG. 17 and may be changed asnecessary.

In FIG. 17, a multicarrier transmission method such as OFDM, forexample, may be used. A single-carrier transmission method may be used,instead. A plurality of symbols, therefore, may exist along a frequencyaxis.

FIG. 18 is a diagram illustrating a second example of the “frameconfiguration of one or more transmission beams (or modulated signals)”transmitted from a base station. The example illustrated in FIG. 18 isan example at a time when the limits of the five communicable rangesillustrated in FIG. 16 have been set.

In FIG. 18, a horizontal axis represents time. There are first to fifthframes 1701_1 to 1701_5, respectively. It is assumed that the firstframe (1701_1), the second frame (1701_2), the third frame (1701_3), thefourth frame (1701_4), and the fifth frame (1701_5) have been subjectedto TDM.

At this time, the first frame (1701_1) is a “frame used by the basestation to transmit up to 16 transmission beams (or modulated signals)”.This frame is used to achieve a communicable area corresponding to anarea inside the ellipse 1651 illustrated in FIG. 16.

The second frame (1701_2) is a “frame used by the base station totransmit up to eight transmission beams (or modulated signals)”. Thisframe is used to achieve a communicable area corresponding to an areainside the ellipse 1652 illustrated in FIG. 16.

The second frame (1701_3) is a “frame used by the base station totransmit up to four transmission beams (or modulated signals)”. Thisframe is used to achieve a communicable area corresponding to an areainside the ellipse 1653 illustrated in FIG. 16.

The fourth frame (1701_4) is a “frame used by the base station totransmit up to two transmission beams (or modulated signals)”. Thisframe is used to achieve a communicable area corresponding to an areainside the ellipse 1654 illustrated in FIG. 16.

The second frame (1701_5) is a “frame used by the base station totransmit one transmission beam (or modulated signal)”. This frame isused to achieve a communicable area corresponding to an area inside theellipse 1655 illustrated in FIG. 16.

The first frame (1701_1) exists in a time section t1, the second frame(1701_2) exists in a time section t2, the third frame (1701_3) exists ina time section t3, the fourth frame (1701_4) exists in a time sectiont4, and the fifth frame (1701_5) exists in a time section t5.

At this time, the time section t1, the time section t2, the time sectiont3, the time section t4, and the time section t5 may be fixed timesections, or may be set as necessary. For example, the time sections maybe set in accordance with the number of terminals that the base stationcommunicates with, positions of the terminals, or the like.

In FIG. 18, the first frame (1701_1), the second frame (1701_2), thethird frame (1701_3), the fourth frame (1701_4), and the fifth frame(1701_5) are discretely arranged. Order in which the first frame(1701_1), the second frame (1701_2), the third frame (1701_3), thefourth frame (1701_4), and the fifth frame (1701_5) are transmitted isnot limited to that illustrated in FIG. 18 and may be changed asnecessary.

In FIG. 18, a multicarrier transmission method such as OFDM, forexample, may be used. A single-carrier transmission method may be used,instead. A plurality of symbols, therefore, may exist along thefrequency axis.

In FIGS. 17 and 18, in addition to the “frames”, symbols may exist suchas “control information symbols (symbols necessary to demodulate anddecode data symbols)” and “pilot symbols, reference symbols, preamblesfor estimating variation in transmission paths, detecting signals,performing frequency synchronization, performing time synchronization,and estimating frequency offsets”. Other symbols may also be included.Information transmitted using the control information symbols includes,for example, “information regarding a modulation method used to generatedata symbols, information regarding a block length (code length) andcode rate of error correction codes, a bit length of data symbols, andinformation necessary for a terminal to link to a base station”.

Since the base station transmits transmission beams using the frameconfiguration illustrated in FIG. 17 or 18, that is, since the basestation transmits a plurality of transmission beams in the same periodof time at the same frequency, an effect of improving data transmissionefficiency can be produced. In addition, an effect of expanding a limitof communication between the base station and terminals can be producedunder a condition that “the sum of average transmission power of thebase station is determined to be a certain value regardless of thenumber of transmission beams (or the number of modulated signals to betransmitted)”.

The frame configurations employed by the base station illustrated inFIGS. 17 and 18 are just examples.

It is assumed, for example, that there are λ or more frames (λis aninteger equal to or larger than 2), i is an integer equal to or largerthan 1 but equal to or smaller than λ, and j is an integer equal to orlarger than 1 but equal to or smaller than λ. An i-th frame is a “frameused by the base station to transmit up to hi transmission beams (ormodulated signals)”, and a j-th frame is a “frame used by the basestation to transmit up to hj transmission beams (or modulated signals)”.In this case, it is sufficient that i and j that satisfy i≠j and hi≠hjexist in the frame configuration.

Alternatively, it is assumed that there are λ or more frames (λ is aninteger equal to or larger than 2), i is an integer equal to or largerthan 1 but equal to or smaller than λ, and j is an integer equal to orlarger than 1 but equal to or smaller than λ. The i-th frame is a “frameused by the base station to transmit up to hi transmission beams (ormodulated signals)”, and the j-th frame is a “frame used by the basestation to transmit up to hj transmission beams (or modulated signals)”.In this case, it is sufficient that all combinations of i and j thatsatisfy i≠j satisfy “hi≠hj” in the frame configuration.

FIG. 19A is a diagram illustrating an example of transmission beamsincluded in each of the frames (the first to fifth frames 1701_1 to1701_5). FIG. 19B is a diagram illustrating an example of streamsincluded in each of the frames (the first to fifth frames 1701_1 to1701_5).

FIG. 19A illustrates the configuration of the transmission beams of thei-th frame illustrated in FIGS. 17 and 18. A horizontal axis in FIG.19A(1) represents time, and there are symbols 1901_1 of a firsttransmission beam of the i-th frame. A horizontal axis in FIG. 19A(2)represents time, and there are symbols 1901_2 of a second transmissionbeam of the i-th frame. Similarly, a horizontal axis in FIG. 19A(ui)represents time, and there are symbols 1901_ui of an ui-th transmissionbeam of the i-th frame.

In the case of the first frame 1701_1 illustrated in FIGS. 17 and 18, u1is an integer equal to or larger than 0 but equal to or smaller than 16.If u1 is equal to or larger than 1, there are symbols of the first tou1-th transmission beams. If u1 is 0, there is no transmission beam.Similarly, in the case of the second frame 1701_2 illustrated in FIGS.17 and 18, u2 is an integer equal to or larger than 0 but equal to orsmaller than 8. If u2 is equal to or larger than 1, there are symbols ofthe first to u2-th transmission beams. If u2 is 0, there is notransmission beam. In the case of the third frame 1701_3 illustrated inFIGS. 17 and 18, u3 is an integer equal to or larger than 0 but equal toor smaller than 4. If u3 is equal to or larger than 1, there are symbolsof the first to u3-th transmission beams. If u3 is 0, there is notransmission beam. In the case of the fourth frame 1701_4 illustrated inFIGS. 17 and 18, u4 is an integer equal to or larger than 0 but equal toor smaller than 2. If u4 is equal to or larger than 1, there are symbolsof the first to u4-th transmission beams. If u4 is 0, there is notransmission beam. In the case of the fifth frame 1701_5 illustrated inFIGS. 17 and 18, u5 is an integer equal to or larger than 0 but equal toor smaller than 1. If u5 is 1, there are symbols of the firsttransmission beam. If u5 is 0, there is no transmission beam.

In FIG. 19A, the symbols 1901_1 of the first transmission beam of thei-th frame, the symbols 1901_2 of the second transmission beam of thei-th frame, . . . , and the symbols 1901_ui of the ui-th transmissionbeam of the i-th frame exist in the time section T4 and are transmittedfrom the base station using the same frequency.

The frames according to the present embodiment may include subframes forassigning the symbols of the above-described transmission beams (ormodulated signals). Alternatively, the frames do not include subframes.Next, the configuration of subframes of a frame will be described.

FIG. 20 is a diagram illustrating a first example of the configurationof subframes of the i-th frame. The i-th frame illustrated in FIG. 20 isthe i-th frame described with reference to FIGS. 17 and 18.

In FIG. 20, a horizontal axis represents time. The i-th frame includes afirst subframe (2001_1) of the i-th frame, a second subframe (2001_2) ofthe i-th frame, . . . , and a vi-th subframe (2001_vi) of the i-thframe. That is, the i-th frame includes vi subframes. FIG. 20illustrates an example in which the subframes are subjected to TDM. Inaddition, vi is an integer equal to or larger than 1. A value of vi isset for each value of i. The value of vi may change over time.

In this case, as described above, the i-th frame is a “frame used by thebase station to transmit up to hi transmission beams (or modulatedsignals)”. In FIG. 20, the number of transmission beams (or modulatedsignals) may be set for each of the subframes of the i-th frame. Thenumber of transmission beams (or modulated signals) of each of thesubframes, however, needs to be equal to or smaller than hi. If the“number of transmission beams (or modulated signals)” of a k-th subframe(k is an integer equal to or larger than 1 but equal to or smaller thanvi) of the i-th frame is bk (bk is an integer equal to or larger than0), therefore, bk is an integer equal to or larger than 0 (or equal toor larger than 1) but equal to or smaller than hi.

As described above, the i-th frame includes subframes. An example of animplementation method and advantageous effects produced thereby will bedescribed with reference to FIG. 21.

FIG. 21 is a diagram illustrating an example of a communication state ofthe base station and terminals according to the present embodiment. InFIG. 21, the same components as those illustrated in FIG. 7, 9, or 15are given the same reference numerals, and description thereof isomitted. FIG. 21 is different from FIG. 15 in that there are atwenty-first terminal (2101), a twenty-second terminal (2102), atwenty-third terminal (2103), and a twenty-fourth terminal (2104)outside the ellipse 799 indicating the “limit of the communicable rangeof the terminals when the base station transmits four transmission beams(or modulated signals)” but inside the ellipse 999 indicating the “limitof the communicable range of the terminals when the base stationtransmits two transmission beams (or modulated signals)”.

In FIG. 21, because of a relationship between the number of transmissionbeams (or modulated signals) and the limit of the communicable range,for example, it is difficult for the base station 700 to communicatewith the eleventh terminal (901), the twelfth terminal (902), thetwenty-first terminal (2101), the twenty-second terminal (2102), thetwenty-third terminal (2103), and the twenty-fourth terminal (2104)using six transmission beams (or modulated signals).

That is, unless the i-th frame is divided into subframes, it isdifficult for the twenty-first terminal (2101), the twenty-secondterminal (2102), the twenty-third terminal (2103), and the twenty-fourthterminal (2104) to communicate with the base station 700 before theeleventh terminal (901) and the twelfth terminal (902) finish thecommunication with the base station 700.

If the i-th frame is divided into subframes, that is, for example, ifthe i-th frame is divided into three subframes (a “subframe 1”, a“subframe 2”, and a “subframe 3”), on the other hand, the base station700 communicates with the eleventh terminal (901) using a firsttransmission beam of the “subframe 1”, the twelfth terminal (902) usinga second transmission beam of the “subframe 1”, the twenty-firstterminal (2101) using a first transmission beam of the “subframe 2”, thetwenty-second terminal (2102) using a second transmission beam of the“subframe 2”, the twenty-third terminal (2103) using a firsttransmission beam of the “subframe 3”, and the twenty-fourth terminal(2104) using a second transmission beam of the “subframe 3”. As aresult, the base station 700 can communicate with the eleventh terminal(901), the twelfth terminal (902), the twenty-first terminal (2101), thetwenty-second terminal (2102), the twenty-third terminal (2103), and thetwenty-fourth terminal (2104).

A method for assigning the terminals to the transmission beams of thesubframes of the i-th frame is not limited to that described above.

In the state illustrated in FIG. 21, for example, a plurality ofsubframes and a plurality of transmission beams may be assigned to a“certain terminal” as described hereinafter.

For example, the base station 700 communicates with the eleventhterminal (901) using the first transmission beam of the “subframe 1”,the twelfth terminal (902) using the second transmission beam of the“subframe 1”, the eleventh terminal (901) using the first transmissionbeam of the “subframe 2”, the twenty-second terminal (2102) using thesecond transmission beam of the “subframe 2”, the twenty-third terminal(2103) using the first transmission beam of the “subframe 3”, thetwenty-fourth terminal (2104) using the second transmission beam of the“subframe 3”, and the twenty-first terminal (2101) using a firsttransmission beam of a “subframe 4”. That is, in this case, a pluralityof subframes are assigned to the eleventh terminal (901).

Alternatively, for example, the base station 700 communicates with theeleventh terminal (901) using the first transmission beam of the“subframe 1”, the twelfth terminal (902) using the second transmissionbeam of the “subframe 1”, the eleventh terminal (901) using the firsttransmission beam of the “subframe 2”, the twenty-second terminal (2102)using the second transmission beam of the “subframe 2”, the twenty-thirdterminal (2103) using the first transmission beam of the “subframe 3”,the twenty-fourth terminal (2104) using the second transmission beam ofthe “subframe 3”, the twenty-first terminal (2101) using the firsttransmission beam of the “subframe 4”, and the twenty first terminal(2101) using a second transmission beam of the “subframe 4”. That is, inthis case, a plurality of subframes are assigned to the eleventhterminal (901), and a plurality of transmission beams are assigned tothe twenty-first terminal (2101).

Alternatively, for example, the base station 700 communicates with theeleventh terminal (901) using the first transmission beam of the“subframe 1”, the twelfth terminal (902) using the second transmissionbeam of the “subframe 1”, the eleventh terminal (901) using the firsttransmission beam of the “subframe 2”, the twenty-second terminal (2102)using the second transmission beam of the “subframe 2”, the twenty-thirdterminal (2103) using the first transmission beam of the “subframe 3”,the twenty-fourth terminal (2104) using the second transmission beam ofthe “subframe 3”, the twenty-first terminal (2101) using the firsttransmission beam of the “subframe 4”, the twenty-first terminal (2101)using the second transmission beam of the “subframe 4”, and thetwenty-first terminal (2101) using a first transmission beam of a“subframe 5”. That is, in this case, a plurality of subframes areassigned to the eleventh terminal (901), and a plurality of subframesand a plurality of transmission beams are assigned to the twenty-firstterminal (2101).

FIG. 22 is a diagram illustrating a second example of the configurationof the subframes of the i-th frame. The i-th frame illustrated in FIG.22 is the i-th frame described with reference to FIGS. 17 and 18.

FIG. 19B will be described as an assumption. FIG. 19B is a diagramillustrating an example of streams included in each of the frames (thefirst to fifth frames 1701_1 to 1701_5) illustrated in FIGS. 17 and 18.

FIG. 19B illustrates the configuration of the streams of the i-th frameillustrated in FIGS. 17 and 18. A horizontal axis in FIG. 196(1)represents time, and there are symbols 1901B_1 of a first stream of thei-th frame. A horizontal axis in FIG. 19B(2) represents time, and thereare symbols 1901B_2 of a second stream of the i-th frame. Similarly, ahorizontal axis in FIG. 19B(ui) represents time, and there are symbols1901B_ui of an ui-th stream of the i-th frame.

In the case of the first frame 1701_1 illustrated in FIGS. 17 and 18, u1is an integer equal to or larger than 0 but equal to or smaller than 16.If u1 is equal to or larger than 1, there are symbols of the first tou1-th streams. If u1 is 0, there is no stream. Similarly, in the case ofthe second frame 1701_2 illustrated in FIGS. 17 and 18, u2 is an integerequal to or larger than 0 but equal to or smaller than 8. If u2 is equalto or larger than 1, there are symbols of the first to u2-th streams. Ifu2 is 0, there is no stream. In the case of the third frame 1701_3illustrated in FIGS. 17 and 18, u3 is an integer equal to or larger than0 but equal to or smaller than 4. If u3 is equal to or larger than 1,there are symbols of the first to u3-th streams. If u3 is 0, there is nostream. In the case of the fourth frame 1701_4 illustrated in FIGS. 17and 18, u4 is an integer equal to or larger than 0 but equal to orsmaller than 2. If u4 is equal to or larger than 1, there are symbols ofthe first to u4-th streams. If u4 is 0, there is no stream. In the caseof the fifth frame 1701_5 illustrated in FIGS. 17 and 18, u5 is aninteger equal to or larger than 0 but equal to or smaller than 1. If u5is 1, there are symbols of the first stream. If u5 is 0, there is nostream.

In FIG. 19B, the symbols 1901B_1 of the first stream of the i-th frame,the symbols 1901B_2 of the second stream of the i-th frame, . . . , andthe symbols 1901B_ui of the ui-th stream of the i-th frame exist in thetime section T4 and are transmitted from the base station using the samefrequency.

In FIG. 22, a horizontal axis represents time, and a vertical axisrepresents frequency (carrier or subcarrier). In FIG. 22, it is assumed,for example, that multicarrier transmission such as OFDM is employed,and symbols exist in a frequency direction.

As illustrated in FIG. 22, the i-th frame includes a first subframe(2201_1) of the i-th frame, a second subframe (2201_2) of the i-thframe, . . . , and a vi-th subframe (2201_vi) of the i-th frame. Thatis, the i-th frame includes vi subframes. FIG. 22 illustrates an examplein which the subframes are subjected to frequency-division multiplexing(FDM). In addition, vi is an integer equal to or larger than 1. A valueof vi is set for each value of i. The value of vi may change over time.

The usage of the subframes is the same as in FIGS. 20 and 21. That is,each subframe may include one or more streams (or modulated signals),and a terminal may be assigned to each subframe or each stream. As aresult, the same advantageous effects as those described with referenceto FIGS. 20 and 21 can be produced.

At this time, a different type of beamforming may be performed for eachsubframe. That is, a transmission beam may be generated for eachsubframe illustrated in FIG. 22. Alternatively, a transmission beam maybe generated for each stream.

FIG. 23 is a diagram illustrating a third example of the configurationof the subframes of the i-th frame. The i-th frame illustrated in FIG.23 is the i-th frame described with reference to FIGS. 17, 18, and thelike.

In FIG. 23, a horizontal axis represents time, and a vertical axisrepresents frequency (carrier or subcarrier). In FIG. 23, it is assumed,for example, that multicarrier transmission such as OFDM is employed,and symbols exist in the frequency direction.

As illustrated in FIG. 23, the i-th frame includes a first subframe(2301_1) of the i-th frame, a second subframe (2301_2) of the i-thframe, a third subframe (2301_3) of the i-th frame, a fourth subframe(2301_4) of the i-th frame, a fifth subframe (2301_5) of the i-th frame,a sixth subframe of the i-th frame (2301_6), . . . , and a vi-thsubframe (2301_vi) of the i-th frame. That is, the i-th frame includesvi subframes. In the example illustrated in FIG. 23, the first subframeof the i-th frame and the second subframe of the i-th frame aresubjected to TDM, and the other subframes are subjected to divisionmultiplexing using a domain configured by frequency and time. Inaddition, vi is an integer equal to or larger than 1. A value of vi isset for each value of i. The value of vi may change over time.

The usage of the subframes is the same as described with reference toFIG. 22. That is, each subframe may include one or more streams (ormodulated signals), and a terminal may be assigned to each subframe oreach stream. As a result, the same advantageous effects as thosedescribed with reference to FIGS. 20 and 21 can be produced.

At this time, a different type of beamforming may be performed for eachsubframe. That is, a transmission beam may be generated for eachsubframe illustrated in FIG. 23. Alternatively, a transmission beam maybe generated for each stream.

FIG. 24 is a diagram illustrating a fourth example of the configurationof the subframes of the i-th frame. The i-th frame illustrated in FIG.24 is the i-th frame described with reference to FIGS. 17, 18, and thelike.

In FIG. 24, a horizontal axis represents time, and a vertical axisrepresents frequency (carrier or subcarrier). In FIG. 24, it is assumed,for example, that multicarrier transmission such as OFDM is employed,and symbols exist in the frequency direction.

As illustrated in FIG. 24, the i-th frame includes a first subframe(2401_1) of the i-th frame, a second subframe (2401_2) of the i-thframe, a third subframe (2401_3) of the i-th frame, a fourth subframe(2401_4) of the i-th frame, a fifth subframe (2401_5) of the i-th frame,. . . , and a vi-th subframe (2401_vi) of the i-th frame. That is, thei-th frame includes vi subframes. In the example illustrated in FIG. 24,the second subframe of the i-th frame and the vi-th subframe of the i-thframe are subjected to FDM, and the other subframes are subjected todivision multiplexing using a domain configured by frequency and time.In addition, vi is an integer equal to or larger than 1. A value of viis set for each value of i. The value of vi may change over time.

The usage of the subframes is the same as described with reference toFIG. 22. That is, each subframe may include one or more streams (ormodulated signals), and a terminal may be assigned to each subframe oreach stream. As a result, the same advantageous effects as thosedescribed with reference to FIGS. 20 and 21 can be produced.

At this time, a different type of beamforming may be performed for eachsubframe. That is, a transmission beam may be generated for eachsubframe illustrated in FIG. 22. Alternatively, a transmission beam maybe generated for each stream.

FIG. 25 is a diagram illustrating a fifth example of the configurationof the subframes of the i-th frame. The i-th frame illustrated in FIG.25 is the i-th frame described with reference to FIGS. 17, 18, and thelike.

In FIG. 25, a horizontal axis represents time, and a vertical axisrepresents frequency (carrier or subcarrier). In FIG. 25, it is assumed,for example, that multicarrier transmission such as OFDM is employed,and symbols exist in the frequency direction.

As illustrated in FIG. 25, the i-th frame includes a first subframe(2501_1) of the i-th frame, a second subframe (2501_2) of the i-thframe, a third subframe (2501_3) of the i-th frame, a fourth subframe(2501_4) of the i-th frame, a fifth subframe (2501_5) of the i-th frame,. . . , a (vi−1)th subframe (2501_(vi−1)) of the i-th frame, and a vi-thsubframe (2501_vi) of the i-th frame. That is, the i-th frame includesvi subframes. In the example illustrated in FIG. 25, the subframes aresubjected to division multiplexing using a domain configured byfrequency and time. In addition, vi is an integer equal to or largerthan 1. A value of vi is set for each value of i. The value of vi maychange over time.

The usage of the subframes is the same as described with reference toFIG. 22. That is, each subframe may include one or more streams (ormodulated signals), and a terminal may be assigned to each subframe oreach stream. As a result, the same advantageous effects as thosedescribed with reference to FIGS. 20 and 21 can be produced.

At this time, a different type of beamforming may be performed for eachsubframe. That is, a transmission beam may be generated for eachsubframe illustrated in FIG. 25. Alternatively, a transmission beam maybe generated for each stream.

The configuration of each of the frames illustrated in FIGS. 17 and 18subjected to time division has been described above. Next, framessubjected to frequency division will be described.

FIG. 26 is a diagram illustrating an example of the “frame configurationof one or more streams (or modulated signals)” transmitted from a basestation. The example illustrated in FIG. 26 is an example in which thelimits of the five communicable ranges illustrated in FIG. 16 have beenset.

In FIG. 26, a horizontal axis represents time, and a vertical axisrepresents frequency (carrier). There are first to fifth frames 2601_1to 2601_5, respectively. It is assumed that the first frame (2601_1),the second frame (2601_2), the third frame (2601_3), the fourth frame(2601_4), and the fifth frame (2601_5) are subjected to FDM. That is,these frames are based on multicarrier transmission such as OFDM.

At this time, the first frame (2601_1) is a “frame used by the basestation to transmit up to sixteen streams (or modulated signals)”. Thisframe is used to achieve the communicable area corresponding to the areainside the ellipse 1651 illustrated in FIG. 16.

The second frame (2601_2) is a “frame used by the base station totransmit up to eight streams (or modulated signals)”. This frame is usedto achieve the communicable area corresponding to the area inside theellipse 1652 illustrated in FIG. 16.

The second frame (2601_3) is a “frame used by the base station totransmit up to four streams (or modulated signals)”. This frame is usedto achieve the communicable area corresponding to the area inside theellipse 1653 illustrated in FIG. 16.

The fourth frame (2601_4) is a “frame used by the base station totransmit up to two streams (or modulated signals)”. This frame is usedto achieve the communicable area corresponding to the area inside theellipse 1654 illustrated in FIG. 16.

The second frame (2601_5) is a “frame used by the base station totransmit one stream (or modulated signal)”. This frame is used toachieve the communicable area corresponding to the area inside theellipse 1655 illustrated in FIG. 16.

The first frame (2601_1) exists in a frequency section F1, the secondframe (2601_2) exists in a frequency section F2, the third frame(2601_3) exists in a frequency section F3, the fourth frame (2601_4)exists in a frequency section F4, and the fifth frame (2601_5) exists ina frequency section F5.

At this time, the frequency section F1, the frequency section F2, thefrequency section F3, the frequency section F4, and the frequencysection F5 may be fixed frequency sections, or may be set as necessary.For example, the frequency sections may be set in accordance with thenumber of terminals that the base station communicates with, positionsof the terminals, or the like.

Order in which the first frame (2601_1), the second frame (2601_2), thethird frame (2601_3), the fourth frame (2601_4), and the fifth frame(2601_5) are arranged along the frequency axis is not limited to thatillustrated in FIG. 26 and may be changed as necessary.

Since the base station transmits streams using the frame configurationillustrated in FIG. 26, that is, since the base station transmits aplurality of streams in the same period of time at the same frequency,an effect of improving data transmission efficiency can be produced. Inaddition, an effect of expanding a limit of communication between thebase station and terminals can be produced under a condition that “thesum of average transmission power of the base station is determined tobe a certain value regardless of the number of streams (or the number ofmodulated signals to be transmitted)”.

The frame configuration employed by the base station illustrated in FIG.26 is just an example.

It is assumed, for example, that there are λ or more frames (λ is aninteger equal to or larger than 2), i is an integer equal to or largerthan 1 but equal to or smaller than λ, and j is an integer equal to orlarger than 1 but equal to or smaller than λ. When i≠j, the i-th frameis a “frame used by the base station to transmit up to hi streams (ormodulated signals)”, and the j-th frame is a “frame used by the basestation to transmit up to hj streams (or modulated signals)”. In thiscase, it is sufficient that i and j that satisfy i≠j and hi≠hj exist inthe frame configuration.

Alternatively, it is assumed that there are λ or more frames (λ is aninteger equal to or larger than 2), i is an integer equal to or largerthan 1 but equal to or smaller than λ, and j is an integer equal to orlarger than 1 but equal to or smaller than λ. The i-th frame is a “frameused by the base station to transmit up to hi streams (or modulatedsignals)”, and the j-th frame is a “frame used by the base station totransmit up to hj streams (or modulated signals)”. In this case, it issufficient that all combinations of i and j that satisfy i≠j satisfy“hi≠hj” in the frame configuration.

Next, the example of the streams of the frames illustrated in FIG. 26will be described with reference to FIG. 19B.

FIG. 19B illustrates an example of the streams included in each of theframes illustrated in FIG. 26 (the first to fifth frames 2601_1 to2601_5). It is assumed that data can be transmitted using each stream.It is assumed, for example, that if there are a first stream and asecond stream, a first piece of data can be transmitted using the firststream and a second piece of data can be transmitted using the secondstream.

FIG. 19B illustrates the configuration of streams of the i-th frameillustrated in FIG. 26. The horizontal axis in FIG. 196(1) representstime, and there are the symbols 1901B_1 of the first stream of the i-thframe. The horizontal axis in FIG. 19B(2) represents time, and there arethe symbols 1901B_2 of the second stream of the i-th frame. Similarly,the horizontal axis in FIG. 19B(ui) represents time, and there are thesymbols 1901B_ui of the ui-th stream of the i-th frame.

In the case of the first frame 2601 illustrated in FIG. 26, u1 is aninteger equal to or larger than 0 but equal to or smaller than 16. If u1is equal to or larger than 1, there are symbols of the first to u1-thstreams. If u1 is 0, there is no stream. Similarly, in the case of thesecond frame 2602 illustrated in FIG. 26, u2 is an integer equal to orlarger than 0 but equal to or smaller than 8. If u2 is equal to orlarger than 1, there are symbols of the first to u2-th streams. If u2 is0, there is no stream. In the case of the third frame 2603 illustratedin FIG. 26, u3 is an integer equal to or larger than 0 but equal to orsmaller than 4. If u3 is equal to or larger than 1, there are symbols ofthe first to u3-th streams. If u3 is 0, there is no stream. In the caseof the fourth frame 2604 illustrated in FIG. 26, u4 is an integer equalto or larger than 0 but equal to or smaller than 2. If u4 is equal to orlarger than 1, there are symbols of the first to u4-th streams. If u4 is0, there is no stream. In the case of the fifth frame 2605 illustratedin FIG. 26, u5 is an integer equal to or larger than 0 but equal to orsmaller than 1. If u5 is equal to or larger than 1, there are symbols ofthe first to u5-th streams. If u5 is 0, there is no stream.

In FIG. 19B, the symbols 1901B_1 of the first stream of the i-th frame,the symbols 1901B_2 of the second stream of the i-th frame, . . . , andthe symbols 1901B_ui of the ui-th stream of the i-th frame exist in thetime section T4 and are transmitted from the base station using the samefrequency.

Next, the configuration of subframes of the frames illustrated in FIG.26 will be described with reference to FIG. 20. FIG. 20 illustrates anexample of the subframes of the i-th frame described with reference toFIG. 26 and the like.

In FIG. 20, the horizontal axis represents time. The i-th frame includesthe first subframe (2001_1) of the i-th frame, the second subframe(2001_2) of the i-th frame, . . . , and the vi-th subframe (2001_vi) ofthe i-th frame. That is, the i-th frame includes the vi subframes. FIG.20 illustrates an example in which the subframes are subjected to TDM.In addition, vi is an integer equal to or larger than 1. The value of viis set for each value of i. The value of vi may change over time.

In this case, as described above, the i-th frame is a “frame used by thebase station to transmit up to hi streams (or modulated signals)”. InFIG. 20, the number of streams (or modulated signals) may be set foreach of the subframes of the i-th frame. The number of streams (ormodulated signals) of each of the subframes, however, needs to be equalto or smaller than hi. If the “number of streams (or modulated signals)”of the k-th subframe (k is an integer equal to or larger than 1 butequal to or smaller than vi) of the i-th frame is bk (bk is an integerequal to or larger than 0), therefore, bk is an integer equal to orlarger than 0 (or equal to or larger than 1) but equal to or smallerthan hi.

As described above, the i-th frame includes subframes. An example of animplementation method and advantageous effects produced thereby will bedescribed with reference to FIG. 21.

FIG. 21 is a diagram illustrating an example of the communication stateof the base station and the terminals according to the presentembodiment. In FIG. 21, the same components as those illustrated in FIG.7, 9, or 15 are given the same reference numerals, and descriptionthereof is omitted. FIG. 21 is different from FIG. 15 in that there arethe twenty-first terminal (2101), the twenty-second terminal (2102), thetwenty-third terminal (2103), and the twenty-fourth terminal (2104)outside the ellipse 799 indicating the “limit of the communicable rangeof the terminals when the base station transmits four streams (ormodulated signals)” but inside the ellipse 999 indicating the “limit ofthe communicable range of the terminals when the base station transmitstwo streams (or modulated signals)”.

In FIG. 21, because of a relationship between the number of streams (ormodulated signals) and the limit of the communicable range, for example,it is difficult for the base station 700 to communicate with theeleventh terminal (901), the twelfth terminal (902), the twenty-firstterminal (2101), the twenty-second terminal (2102), the twenty-thirdterminal (2103), and the twenty-fourth terminal (2104) using six streams(or modulated signals).

That is, unless the i-th frame is divided into subframes, it isdifficult for the twenty-first terminal (2101), the twenty-secondterminal (2102), the twenty-third terminal (2103), and the twenty-fourthterminal (2104) to communicate with the base station 700 before theeleventh terminal (901) and the twelfth terminal (902) finish thecommunication with the base station 700.

If the i-th frame is divided into subframes, that is, for example, ifthe i-th frame is divided into the three subframes (the “subframe 1”,the “subframe 2”, and the “subframe 3”), on the other hand, the basestation 700 communicates with the eleventh terminal (901) using a firststream of the “subframe 1”, the twelfth terminal (902) using a secondstream of the “subframe 1”, the twenty-first terminal (2101) using afirst stream of the “subframe 2”, the twenty-second terminal (2102)using a second stream of the “subframe 2”, the twenty-third terminal(2103) using a first stream of the “subframe 3”, and the twenty-fourthterminal (2104) using a second stream of the “subframe 3”. As a result,the base station 700 can communicate with the eleventh terminal (901),the twelfth terminal (902), the twenty-first terminal (2101), thetwenty-second terminal (2102), the twenty-third terminal (2103), and thetwenty-fourth terminal (2104).

A method for assigning the terminals to the streams of the subframes ofthe i-th frame is not limited to that described above.

In the state illustrated in FIG. 21, for example, a plurality ofsubframes and a plurality of streams may be assigned to a “certainterminal” as described hereinafter.

For example, the base station 700 communicates with the eleventhterminal (901) using the first stream of the “subframe 1”, the twelfthterminal (902) using the second stream of the “subframe 1”, the eleventhterminal (901) using the first stream of the “subframe 2”, thetwenty-second terminal (2102) using the second stream of the “subframe2”, the twenty-third terminal (2103) using the first stream of the“subframe 3”, the twenty-fourth terminal (2104) using the second streamof the “subframe 3”, and the twenty-first terminal (2101) using a firststream of a “subframe 4”. That is, in this case, a plurality ofsubframes are assigned to the eleventh terminal (901).

Alternatively, for example, the base station 700 communicates with theeleventh terminal (901) using the first stream of the “subframe 1”, thetwelfth terminal (902) using the second stream of the “subframe 1”, theeleventh terminal (901) using the first stream of the “subframe 2”, thetwenty-second terminal (2102) using the second stream of the “subframe2”, the twenty-third terminal (2103) using the first stream of the“subframe 3”, the twenty-fourth terminal (2104) using the second streamof the “subframe 3”, the twenty-first terminal (2101) using the firststream of the “subframe 4”, and the twenty-first terminal (2101) using asecond stream of the “subframe 4”. That is, in this case, a plurality ofsubframes are assigned to the eleventh terminal (901), and a pluralityof streams are assigned to the twenty-first terminal (2101).

Alternatively, for example, the base station 700 communicates with theeleventh terminal (901) using the first stream of the “subframe 1”, thetwelfth terminal (902) using the second stream of the “subframe 1”, theeleventh terminal (901) using the first stream of the “subframe 2”, thetwenty-second terminal (2102) using the second stream of the “subframe2”, the twenty-third terminal (2103) using the first stream of the“subframe 3”, the twenty-fourth terminal (2104) using the second streamof the “subframe 3”, the twenty-first terminal (2101) using the firststream of the “subframe 4”, the twenty-first terminal (2101) using thesecond stream of the “subframe 4”, and the twenty-first terminal (2101)using a first stream of a “subframe 5”. That is, in this case, aplurality of subframes are assigned to the eleventh terminal (901), anda plurality of subframes and a plurality of streams are assigned to thetwenty-first terminal (2101).

Next, the configuration of the subframes of the frames illustrated inFIG. 26 will be described with reference to FIGS. 22 to 25. FIG. 22illustrates an example of the configuration of the i-th frame describedwith reference to FIG. 26 and the like different from that illustratedin FIG. 20.

In FIG. 22, the horizontal axis represents time, and the vertical axisrepresents frequency (carrier or subcarrier). In FIG. 22, it is assumed,for example, that multicarrier transmission such as OFDM is employed,and the symbols exist in the frequency direction.

As illustrated in FIG. 22, the i-th frame includes the first subframe(2201_1) of the i-th frame, the second subframe (2201_2) of the i-thframe, . . . , and the vi-th subframe (2201_vi) of the i-th frame. Thatis, the i-th frame includes the vi subframes. FIG. 22 illustrates anexample in which the subframes are subjected to FDM. In addition, vi isan integer equal to or larger than 1. The value of vi is set for eachvalue of i. The value of vi may change over time.

The usage of the subframes is the same as in FIGS. 20 and 21. That is,each subframe may include one or more streams (or modulated signals),and a terminal may be assigned to each subframe or each stream. As aresult, the same advantageous effects as those described with referenceto FIGS. 20 and 21 can be produced.

At this time, a different type of beamforming may be performed for eachsubframe. That is, a transmission beam may be generated for eachsubframe illustrated in FIG. 22. Alternatively, a transmission beam maybe generated for each stream.

FIG. 23 illustrates an example of the configuration of the i-th framedifferent from that illustrated in FIG. 20 or 22.

In FIG. 23, the horizontal axis represents time, and the vertical axisrepresents frequency (carrier or subcarrier). In FIG. 23, it is assumed,for example, that multicarrier transmission such as OFDM is employed,and the symbols exist in the frequency direction.

As illustrated in FIG. 23, the i-th frame includes the first subframe(2301_1) of the i-th frame, the second subframe (2301_2) of the i-thframe, the third subframe (2301_3) of the i-th frame, the fourthsubframe (2301_4) of the i-th frame, the fifth subframe (2301_5) of thei-th frame, the sixth subframe of the i-th frame (2301_6), . . . , andthe vi-th subframe (2301_vi) of the i-th frame. That is, the i-th frameincludes the vi subframes. In the example illustrated in FIG. 23, thefirst subframe of the i-th frame and the second subframe of the i-thframe are subjected to TDM, and the other subframes are subjected todivision multiplexing using the domain configured by frequency and time.In addition, vi is an integer equal to or larger than 1. The value of viis set for each value of i. The value of vi may change over time.

The usage of the subframes is the same as described with reference toFIG. 22. That is, each subframe may include one or more streams (ormodulated signals), and a terminal may be assigned to each subframe oreach stream. As a result, the same advantageous effects as thosedescribed with reference to FIGS. 20 and 21 can be produced.

At this time, a different type of beamforming may be performed for eachsubframe. That is, a transmission beam may be generated for eachsubframe illustrated in FIG. 23. Alternatively, a transmission beam maybe generated for each stream.

FIG. 24 illustrates an example of the configuration of the i-th framedescribed with reference to FIG. 26 and the like different from thatillustrated in FIG. 20, 22, or 23.

In FIG. 24, the horizontal axis represents time, and the vertical axisrepresents frequency (carrier or subcarrier). In FIG. 24, it is assumed,for example, that multicarrier transmission such as OFDM is employed,and the symbols exist in the frequency direction.

As illustrated in FIG. 24, the i-th frame includes the first subframe(2401_1) of the i-th frame, the second subframe (2401_2) of the i-thframe, the third subframe (2401_3) of the i-th frame, the fourthsubframe (2401_4) of the i-th frame, the fifth subframe (2401_5) of thei-th frame, . . . , and the vi-th subframe (2401_vi) of the i-th frame.That is, the i-th frame includes the vi subframes. In the exampleillustrated in FIG. 24, the second subframe of the i-th frame and thevi-th subframe of the i-th frame are subjected to FDM, and the othersubframes are subjected to division multiplexing using the domainconfigured by frequency and time. In addition, vi is an integer equal toor larger than 1. The value of vi is set for each value of i. The valueof vi may change over time.

The usage of the subframes is the same as described with reference toFIG. 22. That is, each subframe may include one or more streams (ormodulated signals), and a terminal may be assigned to each subframe oreach stream. As a result, the same advantageous effects as thosedescribed with reference to FIGS. 20 and 21 can be produced.

At this time, a different type of beamforming may be performed for eachsubframe. That is, a transmission beam may be generated for eachsubframe illustrated in FIG. 22. Alternatively, a transmission beam maybe generated for each stream.

FIG. 25 illustrates an example of the configuration of the i-th framedescribed with reference to FIG. 26 and the like different from thatillustrated in FIG. 20, 22, 23, or 24.

In FIG. 25, the horizontal axis represents time, and the vertical axisrepresents frequency (carrier or subcarrier). In FIG. 25, it is assumed,for example, that multicarrier transmission such as OFDM is employed,and the symbols exist in the frequency direction.

As illustrated in FIG. 25, the i-th frame includes the first subframe(2501_1) of the i-th frame, the second subframe (2501_2) of the i-thframe, the third subframe (2501_3) of the i-th frame, the fourthsubframe (2501_4) of the i-th frame, the fifth subframe (2501_5) of thei-th frame, . . . , the (vi−1)th subframe (2501_(vi−1)) of the i-thframe, and the vi-th subframe (2501_vi) of the i-th frame. That is, thei-th frame includes the vi subframes. In the example illustrated in FIG.25, the subframes are subjected to division multiplexing using thedomain configured by frequency and time. In addition, vi is an integerequal to or larger than 1. The value of vi is set for each value of i.The value of vi may change over time.

The usage of the subframes is the same as described with reference toFIG. 22. That is, each subframe may include one or more streams (ormodulated signals), and a terminal may be assigned to each subframe oreach stream. As a result, the same advantageous effects as thosedescribed with reference to FIGS. 20 and 21 can be produced.

At this time, a different type of beamforming may be performed for eachsubframe. That is, a transmission beam may be generated for eachsubframe illustrated in FIG. 25. Alternatively, a transmission beam maybe generated for each stream.

As described above, by determining the number of transmission beams (thenumber of streams) for each frame and causing the base station totransmit a plurality of frames, the communicable range becomes differentfor each frame, and an effect of expanding a communication distancebetween the base station and terminals can be produced.

The frame configuration, the configuration of transmission beams, theconfiguration of streams, the configuration of subframes, theconfiguration of symbols, and the like described in the presentembodiment are merely examples, and these configurations are not limitedto those described in the present embodiment. For example, the frameconfiguration, the configuration of transmission beams, theconfiguration of streams, the configuration of subframes, theconfiguration of symbols, and the like described in the presentembodiment include symbols such as data symbols, control informationsymbols including control information necessary to demodulate and decodethe data symbols, and pilot symbols, reference symbols, preambles forestimating variation in transmission paths, detecting signals,performing frequency synchronization, performing time synchronization,and estimating frequency offsets. Other symbols may also be included.Information transmitted using the control information symbols includes,for example, information regarding a modulation method used to generatedata symbols, information regarding a block length (code length) andcode rate of error correction codes, a bit length of data symbols, andinformation necessary for a terminal to link to a base station.

With respect to the frames illustrated in FIGS. 17 and 26 and thesubframes illustrated in FIGS. 20, 22, 23, 24, 25, and 26, time division(or TDM), frequency division (or FDM), and time and frequency domaindivision (or time-and-frequency-domain-division multiplexing) have beendescribed. Next, other examples of time boundaries or frequencyboundaries of frames or subframes will be described.

In the case of division in a time direction, for example, a stateillustrated in FIG. 27 is assumed. FIG. 27 is a diagram illustrating anexample of the division in the time direction.

In FIG. 27, a horizontal axis represents time, and a vertical axisrepresents frequency (carrier). FIG. 27 illustrates an example in whicha first domain, a second domain, a third domain, and a fourth domain aredefined in the time direction.

As illustrated in FIG. 27, at a time t1, the first and second domainsexist. At times t2 and t3, the second and third domains exist. The thirdand fourth domains do not overlap in the time direction. The “divisionin the time direction” is defined with these cases included. Forexample, a frame may be subjected to time division such that a pluralityof frames exist at a certain time as illustrated in FIG. 27.Alternatively, a subframe may be subjected to time division such that aplurality of subframes exist at a certain time as illustrated in FIG.27.

Furthermore, as indicated by the first to third domains illustrated inFIG. 27, a domain may have different time widths at differentfrequencies. That is, a domain need not be rectangular in atime-frequency plane. The “division in the time direction” is definedwith these cases included.

In the case of division in the frequency direction, for example, a stateillustrated in FIG. 28 is assumed. FIG. 28 is a diagram illustrating anexample of the division in the frequency direction.

In FIG. 28, a horizontal axis represents frequency (carrier), and avertical axis represents time. FIG. 28 illustrates an example in which afirst domain, a second domain, a third domain, and a fourth domain aredefined in the frequency direction.

As illustrated in FIG. 28, at a carrier c1, the first and second domainsexist. At carriers c2 and c3, the second and third domains exist. Thethird and fourth domains do not overlap in the frequency direction. The“division in the frequency direction” is defined with these casesincluded. For example, a frame may be subjected to frequency divisionsuch that a plurality of frames exist at a certain frequency (carrier)as illustrated in FIG. 28. Alternatively, a subframe may be subjected tofrequency division such that a plurality of subframes exist at a certainfrequency (carrier) as illustrated in FIG. 28.

Furthermore, as indicated by the first to third domains illustrated inFIG. 28, a domain may have different frequency widths at differenttimes. That is, a domain need not be rectangular in a time-frequencyplane. The “division in the frequency direction” is defined with thesecases included.

In addition, when a frame and/or a subframe is subjected to time andfrequency domain division (or time-and-frequency-domain-divisionmultiplexing), the division in the time direction may be performed asillustrated in FIG. 27 and the division in the frequency direction maybe performed as illustrated in FIG. 28. That is, a domain of a frame ora subframe in a time-frequency plane may have different frequency widthsat different times and different time widths at different frequencies.

In the above description, for example, FIG. 19A illustrates transmissionbeams of a frame, and FIG. 19B illustrates streams of a frame.Transmission beams and streams both correspond to modulated symbolsequences transmitted to terminals.

An example of the basic configuration of a communication apparatus suchas the base station or the access point that has been described indetail above will be described with reference to FIG. 29. Acommunication apparatus 2900 according to the present embodimentincludes a signal processor 2901 (e.g., corresponds to the signalprocessor 102 illustrated in FIGS. 1 and 3) that adjusts transmissiontimings and/or frequencies of modulated symbol sequences for eachterminal such that the modulated symbol sequences are transmitted usinga frame corresponding to a communicable range within which the terminalis located among a plurality of frames based on time and frequency bandsand a weighting synthesizer 2902 (e.g., corresponds to themultiplication units 204_1 to 204_4 illustrated in FIG. 2 or theweighting synthesizer 301 illustrated in FIG. 3) that weights themodulated symbol sequences and transmits the modulated symbol sequencesfrom antennas. Each frame is set such that the number of modulatedsymbol sequences that can be simultaneously transmitted in the sameperiod of time and the same frequency band becomes different betweencommunicable ranges. In addition, each frame includes a plurality ofsubframes specified by performing time division and/or frequencydivision on the frame. The signal processor 2901 assigns, to each of theplurality of subframes of each frame, modulated symbol sequences equalto or fewer than the number of modulated symbol sequences that can besimultaneously transmitted set for the frame.

In the above description, there has been a sentence, “An upper limit ofthe sum of average transmission power is determined to be a certainvalue regardless of the number of transmission beams (or the number ofmodulated signals to be transmitted)”. A supplementary explanation ofthis will be given hereinafter.

It is assumed, for example, that a transmission device of a base stationor a terminal includes a total of four transmission antennas, namely atransmission antenna #A, a transmission antenna #B, a transmissionantenna #C, and a transmission antenna #D.

In a first case, for example, the transmission antenna #A transmits amodulated signal A with an average transmission power of 1 watt, thetransmission antenna #B transmits a modulated signal B with an averagetransmission power of 1 watt, the transmission antenna #C transmits amodulated signal C with an average transmission power of 1 watt, and thetransmission antenna #D transmits a modulated signal D with an averagetransmission power of 1 watt. In the first case, the sum of averagetransmission power is 4 watts.

In a second case, the transmission antenna #A transmits the modulatedsignal A with an average transmission power of a watt, the transmissionantenna #B transmits the modulated signal B with an average transmissionpower of b watt, the transmission antenna #C transmits the modulatedsignal C with an average transmission power of c watt, and thetransmission antenna #D transmits the modulated signal D with an averagetransmission power of d watt. It is assumed that a, b, c, and d are realnumbers equal to or larger than 0.

When the same upper limit of the sum of average transmission power isemployed in the second case and the first case, that is, when the upperlimit of the sum of average transmission power in the second case is 4watts, a+b+c+d=4 watts applies; however, a+b+c+d≤4 may be used, instead.Although a case in which there are four modulated signals has beendescribed in the first and second cases, the above rule (the rule thatthe upper limit of the sum of average transmission power be determinedto be a certain value) applies regardless of the number of modulatedsignals.

In addition, although a case in which modulated signals are transmittedhas been described in the first and second cases, the same rule alsoapplies when transmission beams (or streams), not modulated signals, aretransmitted.

More specifically, in a third case, for example, a transmission beam (ora stream) E is transmitted with an average transmission power of 1 watt,a transmission beam (or a stream) F is transmitted with an averagetransmission power of 1 watt, a transmission beam (or a stream) G istransmitted with an average transmission power of 1 watt, and atransmission beam (or a stream) H is transmitted with an averagetransmission power of 1 watt. In the third case, the sum of averagetransmission power is 4 W.

In a fourth case, the transmission beam (or the stream) E is transmittedwith an average transmission power of e watt, the transmission beam (orthe stream) F is transmitted with an average transmission power of fwatt, the transmission beam (or the stream) G is transmitted with anaverage transmission power of g watt, and the transmission beam (or thestream) H is transmitted with an average transmission power of h watt.It is assumed that e, f, g, and h are real numbers equal to or largerthan 0.

When the same upper limit of the sum of average transmission power isemployed in the third and fourth cases, that is, when the upper limit ofthe sum of average transmission power in the fourth case is 4 watts,e+f+g+h=4 watts applies; however, e+f+g+h≤4 may be used, instead.Although a case in which there are four transmission beams (streams) hasbeen described in the third and fourth cases, the above rule (the rulethat the upper limit of the sum of average transmission power bedetermined to be a certain value) applies regardless of the number oftransmission beams.

Although the terms “frame” and “subframe” are used herein, the termsused are not limited to these. The essence of the present disclosure isnot affected even if other terms such as “slot” and “sub-slot”, “stream”and “sub-stream”, or “segment”, and “sub-segment” are used.

It is needless to say that the embodiments and other elements describedherein may be combined with one another and implemented.

In addition, the embodiments and other elements are merely examples andalthough a “modulation method, a method of error correction coding(error correction codes, a code length, and a code rate used, etc.),control information, and the like” are taken as an example, for example,the embodiments and other elements can be implemented with the sameconfiguration by applying other types of “modulation method, method oferror correction coding (error correction codes, a code length, and acode rate used, etc.), control information, and the like”.

With respect to the modulation method, the embodiments and otherelements described herein can be implemented even if a modulation methodother than the modulation method described herein is used. For example,amplitude and phase-shift keying (APSK) (e.g., 16-APSK, 64-APSK,128-APSK, 256-APSK, 1024-APSK, 4096-APSK, etc.), pulse-amplitudemodulation (PAM) (e.g., 4-PAM, 8-PAM, 16-PAM, 64-PAM, 128-PAM, 256-PAM,1024-PAM, 4096-PAM, etc.), phase-shift keying (PSK) (e.g., binary PSK(BPSK), quadrature PSK (QPSK), 8-PSK, 16-PSK, 64-PSK, 128-PSK, 256-PSK,1024-PSK, 4096-PSK, etc.), quadrature amplitude modulation (QAM) (e.g.,4-QAM, 8-QAM, 16-QAM, 64-QAM, 128-QAM, 256-QAM, 1024-QAM, 4096-QAM,etc.), or the like may be used, and uniform mapping or non-uniformmapping may be performed in each modulation method. In addition, amethod for arranging 2, 4, 8, 16, 64, 128, 256, or 1024 signal points orthe like (a modulation method including 2, 4, 8, 16, 64, 128, 256, or1024 signal points or the like) on an in-phase/quadrature (I-Q) plane isnot limited to a method for arranging signal points in the modulationmethod described herein.

The transmission device herein is considered to be included in acommunication/broadcasting apparatus such as a broadcasting station, abase station, an access point, a terminal, or a mobile phone. At thistime, the reception device is considered to be included in acommunication apparatus such as a television set, a radio, a terminal, apersonal computer, a mobile phone, an access point, or a base station.In addition, the communication apparatus in the present disclosure maybe an apparatus having a communication function, and a mode may beemployed in which the apparatus can be connected to an apparatus forexecuting an application, such as a television set, a radio, a personalcomputer, or a mobile phone, through a some kind of interface. Inaddition, in the present embodiment, symbols other than data symbols,such as pilot symbols (preambles, unique words, postambles, referencesymbols, etc.) or symbols for control information, may be arranged in aframe in any manner. Although such symbols are called pilot symbols andsymbols for control information here, any names may be used because whatmatters are functions.

The pilot symbols may be any known symbols modulated in transmission andreception devices using PSK modulation (or the reception device maysynchronize the symbols transmitted from the transmission device toidentify the symbols). The reception device performs frequencysynchronization, time synchronization, channel estimation (CSI) (of eachmodulated signal), detection of signals, and the like using thesesymbols.

In addition, the symbols for control information are symbols fortransmitting information (e.g., a modulated method, a method of errorcorrection coding, a code rate of the method of error correction codingused for communication, setting information in a higher layer, etc.)necessary to be transmitted to a communication target in order toachieve communication of information other than data (such as anapplication).

The present disclosure is not limited to the embodiments and may bemodified in various manners and implemented. For example, although acase in which a communication apparatus achieves the present disclosurehas been described in the embodiments, the present disclosure is notlimited to this. The communication method may be implemented assoftware, instead.

For example, a program for achieving the communication method may bestored in a read-only memory (ROM), and a central processor (CPU) mayexecute the program.

In addition, the program for achieving the communication method may bestored in a computer-readable storage medium. The program stored in thestorage medium may be recorded in a random-access memory (RAM) of acomputer, and the computer may operate in accordance with the program.

In addition, the components described in the above embodiments and thelike may be achieved through large-scale integration (LSI) typically asan IC. Each of these may be individually fabricated as a chip, or someor all of the components in each embodiment may be fabricated as a chip.Although the term LSI is used here, a term such as IC, system LSI,super-LSI, ultra-LSI may be used, instead, depending on a degree ofintegration. A method for fabricating an integrated circuit is notlimited to LSI, and an integrated circuit may be achieved by a dedicatedcircuit or a general-purpose processor. A field-programmable gate array(FPGA) that can be programmed after an LSI circuit is fabricated or areconfigurable processor that can reconfigure connections and settingsof circuit cells inside an LSI circuit may be used. Furthermore, if atechnique for fabricating an integrated circuit that replaces LSIappears as a result of evolution of semiconductor technologies orderivative technologies, the function blocks may naturally be integratedusing the technique. One such possibility is application ofbiotechnology.

It is suitable to use the present disclosure as a communicationapparatus such as a base station, an access point, or a terminal.

What is claimed is:
 1. A communication apparatus for performingdirective transmission using a plurality of antenna elements, thecommunication apparatus comprising: a signal processor which, inoperation, determines transmission timing and/or a frequency fortransmitting a modulated symbol sequence for each of a plurality ofterminals, wherein the transmission timing and/or the frequency for eachof the plurality of terminals is located within a frame corresponding toa communicable range to which corresponding one of the plurality ofterminals belongs, the frame being one of a plurality of frames definedby time and frequency bands; and a weighting synthesizer which, inoperation, applies weights to each of the plurality of modulated symbolsequences and, in operation, transmits the weighted plurality ofmodulated symbol sequences from the plurality of antenna elements,wherein a number of modulated symbol sequences that can besimultaneously transmitted in a same period of time and a same frequencyband is different depending on communicable ranges in each of theplurality of frames, each of the plurality of frames including aplurality of subframes specified by performing time division and/orfrequency division, and wherein the signal processor allocates, to eachof the plurality of subframes, one or more modulated symbol sequences,the number of which is equal to or fewer than the number of modulatedsymbol sequences that can be simultaneously transmitted.
 2. Thecommunication apparatus according to claim 1, wherein, if a firstmodulated symbol sequence for a first terminal located within a firstcommunicable range is to be transmitted, the signal processor assignsthe first modulated symbol sequence for the first terminal to a frame towhich a first number of modulated symbol sequences corresponding to thefirst communicable range is set, and the weighting synthesizer generatestransmission beams, the number of which is equal to or fewer than thefirst number of modulated symbol sequences for the frame to which thefirst number of modulated symbol sequences is set, and wherein, if asecond modulated symbol sequence for a second terminal located within asecond communicable range, which is wider than the first communicablerange, but located outside the first communicable range is to betransmitted, the signal processor assigns the second modulated symbolsequence for the second terminal to a frame to which a second number ofmodulated symbol sequences corresponding to the second communicablerange is set, and the weighting synthesizer generates transmissionbeams, the number of which is equal to or fewer than the second numberof modulated symbol sequences for the frame to which the second numberof modulated symbol sequences is set.
 3. The communication apparatusaccording to claim 2, wherein the first number of modulated symbolsequences is a maximum number of transmission beams that can besimultaneously transmitted in the same period of time and the samefrequency band within the first communicable range, wherein the secondnumber of modulated symbol sequences is a maximum number of transmissionbeams that can be simultaneously transmitted in the same period of timeand the same frequency band within the second communicable rangeexcluding the first communicable range, and wherein the first number ofmodulated symbol sequences is larger than the second number of modulatedsymbol sequences.
 4. The communication apparatus according to claim 2,wherein, if a third modulated symbol sequence for a third terminallocated within a third communicable range, which is wider than thesecond communicable range, but located outside the second communicablerange is to be transmitted, the signal processor assigns the thirdmodulated symbol sequence for the third terminal to a frame to which athird number of modulated symbol sequences corresponding to the thirdcommunicable range is set, and the weighting synthesizer generatestransmission beams, the number of which is equal to or fewer than thethird number of modulated symbol sequences for the frame to which thethird number of modulated symbol sequences is set.
 5. The communicationapparatus according to claim 4, wherein the third number of modulatedsymbol sequences is a maximum number of transmission beams that can besimultaneously transmitted in the same period of time and the samefrequency band within the third communicable range, and wherein thesecond number of modulated symbol sequences is larger than the thirdnumber of modulated symbol sequences.
 6. The communication apparatusaccording to claim 1, further comprising: a receiver that receiveschannel state information regarding a channel state estimated by each ofthe plurality of terminals, wherein the weighting synthesizer generatesweighting coefficients for generating respective transmission beamsbased on the received channel state information.
 7. The communicationapparatus according to claim 1, wherein a maximum value of average powerfor transmitting a transmission signal is a certain value regardless ofthe number of modulated symbol sequences set that are to each of theplurality of frames.
 8. The communication apparatus according to claim1, wherein the plurality of antenna elements is a group of antennaelements for massive multiple-input and multiple-output.
 9. Acommunication method used by a communication apparatus for performingdirective transmission using a plurality of antenna elements, thecommunication method comprising: determining a transmission timingand/or a frequency for transmitting a modulated symbol sequence for eachof a plurality of terminals, wherein the transmission timing and/or thefrequency for each of the plurality of terminals is located within aframe corresponding to a communicable range to which corresponding oneof the plurality of terminals belongs, the frame being one of aplurality of frames defined by time and frequency bands; and applyingweights to each of the plurality of modulated symbol sequences andtransmitting the weighed plurality of modulated symbol sequences fromthe plurality of antenna elements, wherein a number of modulated symbolsequences that can be simultaneously transmitted in a same period oftime and a same frequency band is different depending on communicableranges in each of the plurality of frames, each of the plurality offrames including a plurality of subframes specified by performing timedivision and/or frequency division, and wherein modulated symbolsequences, the number of which is equal to or fewer than the number ofmodulated symbol sequences that can be simultaneously transmitted areallocated to each of the plurality of subframes.